| PLAN CODE | PLAN | SUBJECT CODE | COURSE | DURATION | CONTENTS |
|---|---|---|---|---|---|
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980037 | Design, Operation and Maintenance of Steam Power Plants | Semester 1 | I. INTRODUCTION. II. COMBUSTION PRINCIPLES. III. STEAM GENERATORS. IV. STEAM TURBINES. V. STEAM TURBINE LOSSES. VI. MONITORING AND TESTING. VII. STEAM TURBINE REGULATION. VIII. STEAM TURBINE DAMAGE IX. EMISSIONS FROM STEAM TURBINE PLANTS. X. OPERATION AND MAINTENANCE. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210012 | Fundamentals of Automatic Control | Semester 1 | System modeling and identification. Time-response analysis. Stability analysis. Principles and techniques of system and process control. Design and implementation of basic control systems. Introduction to logic automation. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210001 | Physics I | Semester 1 | Mechanics, oscillations and waves. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210008 | Graphic expression | Semester 2 | THEMATIC BLOCKS 1.- Normalization. 2.- Applied representation systems. 3.- CAD. DEVELOPED SYLLABUS Block I Topic 1: Standardization of Technical Drawings. Topic 2: Views, Sections and Cuts. Topic 3: Dimensioning. Topic 4: Dimensioning with tolerances. Topic 5: Geometric tolerances and surface states. Topic 6: Fixed and removable joints. Topic 7: Standardized machine elements Topic 8: Interpretation of mechanical assemblies. Block II Topic 9: Representation Theory. Topic 10: Representation systems. The Direct Method. Topic 11: Dihedral system. Distances, Angles and Sections. Topic 12: Curves and Surfaces for constructive application. Block III Topic 13: Computer-Aided Drawing. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270064 | Taxation and Business Management | Semester 2 | BLOCK I.- TAX ASPECTS OF THE COMPANY TOPIC 1.- THE COMPANY. TOPIC 2.- BASIC TAX CONCEPTS. TOPIC 3.- START OF ACTIVITY. BLOCK II.- MAIN TAXES TOPIC 4.- ECONOMIC ACTIVITY TAX. TOPIC 5.- PERSONAL INCOME TAX. TOPIC 6.- CORPORATION TAX. TOPIC 7.- VALUE ADDED TAX. TOPIC 8.- TRANSFER AND STATE-OF-THE-ART TAX. TOPIC 9.- LOCAL TAXES. BLOCK III.- TAX PROCEDURE TOPIC 10.- TAX PROCEDURE. COLLECTION. INFRINGEMENTS, PENALTIES AND TAX OFFENSES. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280040 | Design of Electronic Circuits and Systems | Semester 1 | Knowledge of noise and interference sources in electronic circuits and appropriate design techniques to minimize them. Ability to design electronic circuits with analog, digital, and power components. Knowledge of microelectronic design. Knowledge of the technologies used to manufacture electronic circuits. Knowledge of commercially available resources for the development of electronic systems. Knowledge of electronic circuit design tools. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280016 | Industrial automation | Semester 2 | CONTENT: Introduction to automation. Production systems. Logical automation. Practical applications of automation. THEMATIC BLOCKS: Topic 1: Introduction to automation Topic 2: Industrial automation Topic 3: Specification languages Topic 4: Programmable logic controllers Topic 5: Industrial communications Topic 6: Supervision and control systems Topic 7: Automation of production systems |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280043 | Electronic Circuit and Systems Design Laboratory | Semester 1 | Ability to design electronic circuits with analog, digital, and power components. Knowledge of micro- and nano-electronic design. Knowledge of the technologies used for manufacturing electronic circuits. Knowledge of electronic circuit design tools. Ability to design signal conditioning circuits for common sensors in the field of measurement and control systems. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280003 | Mathematics I | Semester 1 | Topic 1.- Complex numbers. Polynomials. 1.1.- Complex numbers. Binomial form. Operations and properties. Exponential form. Powers and roots. Geometric applications in the plane. 1.2.- Polynomials. Factorization of polynomials. The Fundamental Theorem of Algebra. The roots of a real polynomial. Topic 2.- Matrices, determinants and systems of linear equations. 2.1.- Matrices. Operations. Properties. 2.2.- Determinants. Definition and properties. 2.3.- Systems of linear equations. Matrix notation. Row reduction and echelon forms. Rouché-Frobenius theorem. Cramer's rule. 2.4.- Solving systems of linear equations. Gauss-Jordan method. Calculating the inverse of a square matrix. 2.5.- The solution set of a system of linear equations. Linear combinations. Homogeneous systems. Complete systems. 2.6.- Matrix transformations. Transformation associated with a matrix. Geometric examples. Topic 3.- Vector spaces. Linear transformations. 3.1.- Vector spaces and subspaces. 3.2- Coordinate vector spaces. Null space and column space of a matrix. Linear dependence and independence. Parametric equations and implicit equations of a subspace. 3.3.- Linear transformations. Definition and properties. Associated matrix. 3.4.- Bases of a subspace. Coordinates. Dimension. Rank of a matrix. The rank theorem. Changes of basis. 3.5.- Sum and intersection of subspaces. Topic 4.- Diagonalization of endomorphisms. 4.1.- Eigenvalues and eigenvectors. Definition and properties. The characteristic equation. The Cayley-Hamilton theorem. 4.2.- Diagonalization. Criteria. 4.3.- Introduction to block diagonalization and matrix exponential. 4.4.- Applications of eigenvalue and eigenvector calculus. Topic 5.- Euclidean and unitary vector space. 5.1.- The scalar product. Orthogonality and best approximation. Norm, distance, angles, and orthogonality. Cauchy-Schwarz inequality, triangle inequality, Pythagorean theorem. 5.2.- The orthogonal complement of a subspace. 5.3.- Orthogonal bases. Orthogonal bases of a subspace. The Gram-Schmidt method. Orthogonal matrices. 5.4.- Orthogonal projection. Orthogonal projection onto a subspace. The best approximation theorem. Topic 6.- Real symmetric matrices and quadratic forms. 6.1.- Quadratic forms. Definition and associated symmetric matrix. Rank and sign. Reductions to sums of squares. Sylvester's law of inertia. Classification. 6.2.- Symmetric and Hermitian matrices. Orthogonal diagonalization (resp. unitary) of symmetric matrices (resp. Hermitian). The principal axes theorem. Topic 7.- Euclidean affine space. Motions. Conics and quadrics. 7.1.- Euclidean affine space. Motions. 7.2.- Motions in the plane. Translations. Homothecies. Rotations. Projections. Symmetries. Gliding symmetries. Linear transformations in the plane. 7.3.- Motions in space. Translations. Projections. Homothecies. Symmetries. Rotations. Helical motions. Linear transformations in space. 7.4.- Conics. Reduced equations. Conic sections. Metric definition and notable elements. The focal property. Reduced equation of an unrotated conic. Parametric equations. 7.5.- Quadrics. Reduced equations. Reduced equation of an unrotated quadric. Ellipsoids. Hyperboloids and the cone. Paraboloids. Cylinders and degenerate quadrics. 7.6.- Conics and quadrics (II). Reduction of a rotated conic. Reduction of a rotated quadric. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560048 | Applied Optics | Semester 2 | Optical observation instruments. Photonics. Digital cameras. 2D and 3D visualization systems and techniques. Non-visible imaging systems. Optical technologies for engineering. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560037 | Solar energy | Semester 2 | Resource assessment. Technology, design, operation, maintenance, and exploitation of solar energy facilities. |
| M143 | Master's Degree in Aeronautical Engineering | 51430014 | Reaction engines design | Semester 1 | THEMATIC BLOCKS 1. POWER GENERATION AND AIR PROPULSION CYCLES COMPRESSED JETS -Definitions: Turbojet with/without afterburner. Turbofan. Turboprop. -Components: dynamic intake, combustion chamber, propulsion nozzle, turbomachinery - Actual characterization of the components - Optimal configuration of power cycles for air propulsion - Technological limitations 2. AERODERIVATIVE GAS TURBINES - Characteristics - Differences with compressor jets 3. AUXILIARY SYSTEMS FOR COMPRESSED JETS - Definition of components - Characterization - Service limitations 4. PROPULSION SYSTEMS TESTING -Thrust bench: components, test parameters - Regulations |
| M146 | Master's Degree in Industrial Engineering | 51460062 | Materials Engineering | Semester 2 | BLOCK I: INTRODUCTION TO MATERIALS ENGINEERING Topic 1: Metallic Materials Topic 2: Ceramic Materials Topic 3: Polymeric Materials Topic 4: Composite Materials BLOCK II: MECHANICAL CHARACTERIZATION OF MATERIALS Topic 5.- Introduction to the characterization of materials Topic 6.- Characterization of metallic materials Topic 7.- Characterization of fiber-reinforced composite materials Topic 8.- Characterization of adhesives BLOCK III. POWDER METALLURGY Topic 9: Introduction and manufacture of powders. Topic 10: Powder metallurgical routes. Topic 11: Products and applications BLOCK IV: MAGNETIC MATERIALS Topic 12. Types of magnetic materials Topic 13. Hysteresis curve Topic 14. Hard magnetic materials Topic 15. Soft magnetic materials Topic 16. Market and potential applications BLOCK V: ENVIRONMENTAL DEGRADATION AND PROTECTION Topic 17: Oxidation and corrosion Topic 18: Corrosion prevention methods Topic 19. Wear Topic 20. Coatings Topic 21: Environmental degradation of ceramics and polymers BLOCK VI: MATERIALS SELECTION Topic 22. Industrial design Topic 23. Selection by the Asbhy method (I) Topic 24. Selection by the Asbhy method (II) |
| 197 | Degree in Aerospace Engineering | 1970039 | Solid mechanics | Semester 2 | The Elastic Problem. Inelastic Behavior, Plasticity. Non-Isotropic Behavior, Composite Materials. Fracture Mechanics. |
| M164 | Master's Degree in Electrical Energy Systems | 51640001 | Transient and Dynamic Analysis of Electrical Systems | Semester 2 | Block 1. Electromagnetic Systems Topic 1.1: Introduction to transient phenomena in electrical systems Topic 1.2: Transients in power lines Topic 1.3: Case studies Block 2. Electromechanical Systems Topic 2.1: Electromechanical modeling of synchronous machines Topic 2.2: Generator controller modeling (AVR, GOV and PSS) Topic 2.3: Differential/Algebraic Systems and their analysis Topic 2.4: Power-frequency inertial response Topic 2.5: Transient stability |
| M190 | Master's Degree in Civil Engineering (2019) | 51900006 | Rational Mechanics Complements | Semester 1 | Extension to Kinematics and Vectorial Dynamics of Rigid Bodies. Analytical Formulation of Mechanics. Extension to Impulsive Dynamics. |
| 203 | Degree in Industrial Technology Engineering | 2030129 | Waste Management and Treatment | Semester 1 | Waste characterization and management study. Waste treatment techniques. Landfill Chapter I. Waste. Introduction. General problems Chapter II. Legislation Chapter III. Urban waste management and collection systems Chapter IV. Material processing and separation technologies Chapter V. Biological waste treatment. Composting Chapter VI. Hazardous waste management and characterization Chapter VII. Stabilization/Solidification treatments Chapter VIII. Thermal treatments. Incineration Chapter IX. Remediation of contaminated soils Chapter X. Waste landfill Chapter XI. Radioactive waste management Chapter XII. Special waste management |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930039 | Environmental Management in Industry | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. |
| M228 | Master's Degree in Operation of Space Systems | 52280005 | Ground segment and on-board computer | Semester 1 | Ground stations; ground segment management; payload ground support; operations; data processing and correction |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280015 | Circuit theory | Semester 1 | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines |
| 199 | Degree in Telecommunications Technology Engineering | 1990025 | Mathematical methods | Semester 1 | Knowledge and use of numerical methods for solving problems of interest in Telecommunications Engineering and their implementation through an interactive-computational environment |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040008 | AI in Image, Audio and Video | Semester 1 | Multimedia audio, video, and image signals. Machine learning and deep artificial neural networks. Applications to voice, audio, image, and video analysis. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210036 | Plastics, ceramics and composites (IRM) | Semester 2 | Synthesis and processing of thermoplastics, thermosets, and elastomers. Nature and processing of structural ceramics. Selection of materials based on their properties. Science and technology of polymer, metal, and ceramic matrix composites. |
| 208 | Degree in Chemical Engineering | 2080011 | Chemistry Extension | Semester 1 | Organic and Inorganic Chemistry applied to Engineering. CHAPTER I. INORGANIC CHEMISTRY TOPIC 1. ACID-BASE EQUILIBRIA TOPIC 2. PRECIPITATION AND COMPLEX FORMATION EQUILIBRIA CHAPTER II. INTRODUCTION TO ORGANIC CHEMISTRY TOPIC 3. ORGANIC COMPOUNDS TOPIC 4. ELECTRONIC STRUCTURE AND PROPERTIES OF ORGANIC MOLECULES TOPIC 5. ORGANIC REACTIONS CHAPTER III. HYDROCARBONS TOPIC 6. ALIPHATIC HYDROCARBONS TOPIC 7. ALKENES. POLYMERIZATION TOPIC 8. PROPERTIES OF POLYMERS TOPIC 9. AROMATIC HYDROCARBONS TOPIC 10. SOURCES OF HYDROCARBONS |
| 199 | Degree in Telecommunications Technology Engineering | 1990040 | Transmission Media | Semester 1 | Guided electromagnetic waves. TE, TM, TEM modes. Transmission lines. Characteristic impedance. Circuit analysis in steady-state and transient sinusoidal conditions. Smith chart. Propagation technologies. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960044 | Transportation and Distribution Networks | Semester 1 | BLOCK I: Flow in networks - The concept of graph - The flow model in networks - The minimum route problem - The maximum flow problem - The transport problem - Other flow models in networks BLOCK II: Transport and logistics networks - Location - Design of transport and distribution routes |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280078 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830004 | Design of Water Treatment Plants | Semester 1 | Water purification methods. Drinking water treatment. Water treatment plant calculations. Management and operation of water treatment systems. Water disposal and reuse. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900032 | Transportation Planning | Semester 1 | Transportation planning, functions and modes of transportation, urban transportation, management of public transportation services, demand, costs, logistics, and financing of transportation infrastructure and services. Urban, interurban, and regional transportation. Planning decisions and alternatives. Data collection, processing, and diagnosis. Analysis of supply and demand for infrastructure and services. Transportation costs. Logistics for the transportation of passengers and goods. Project design, evaluation, and prognosis. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280002 | Computing | TO | Computer fundamentals. Algorithms. Programming. Introduction to operating systems, databases, and software with applications in engineering. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990014 | Advanced Separation Processes | Semester 1 | Multicomponent distillation Adsorption and ion exchange systems Crystallization Membrane separation processes Non-conventional separation systems |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830013 | Numerical Methods in Chemical and Environmental Engineering | Semester 1 | Introduction to MATLAB and Numerical Analysis. Systems of linear equations. Interpolation. Nonlinear optimization and equation solving. Numerical methods for ordinary and partial differential equations. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930031 | Life cycle analysis | Semester 1 | Block 0: PROJECT Block 1. INTRODUCTION AND APPLICABLE REGULATIONS FOR LCA Block 2. LCA METHODOLOGIES. PHASES OF A LCA Block 3. TOOLS FOR LCA PREPARATION: DATABASES AND PROGRAMS Block 4. PRACTICAL CASES AND EXAMPLES OF LCAs |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320009 | helicopters | Semester 2 | Rotor aerodynamics. Performance. Blade dynamics. Conceptual design. |
| 208 | Degree in Chemical Engineering | 2080019 | Fundamentals of Chemical Engineering | Semester 2 | Introduction to Chemical Engineering. Material and Energy Balances |
| 208 | Degree in Chemical Engineering | 2080010 | General chemistry | Semester 2 | Structures and states of matter. Physical-chemical systems and transformations. Properties of chemical reactions: kinetics, spontaneity, equilibria. Organic chemistry. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210049 | Photovoltaic Installations | Semester 1 | 1. Introduction 2. Current situation at global, European, and national levels 2. Fundamentals of geometry and solar radiation 3. Photovoltaic effect, cells, modules, and solar generators 4. Storage systems, regulation, and inverters in PV systems 5. Design and calculation of PV systems. Configuration and applicable legislation |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210026 | Combustion Technology | Semester 1 | Lesson 1. Typology, classification and applications of thermal generators Lesson 2. Basic concepts of combustion Lesson 3. Combustion. Mass balance. Gas analysis Lesson 4. Thermal effects of combustion Lesson 5. Generalities of heat transfer in homes Lesson 6. Aerodynamics of industrial flames I: jet without chemical reaction Lesson 7. Aerodynamics of industrial flames II: jet with chemical reaction Lesson 8. Radiation in combustion atmospheres Lesson 9. Radiant properties of combustion atmospheres Lesson 10. Simplified resolution of radiant exchange in homes Lesson 11. Characterization of heat transfer in homes Lesson 12. Design of thermal generators Lesson 14. Operation of thermal generators Practice 1. Preliminary project of a thermal generator Practice 2. CFD model: thermoaeraulic study in homes Practice 3. Monte Carlo model: detailed study of radiation in homes |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210013 | Power Electronics (EIDTE) | Semester 1 | - Electronic device technology for energy management. - Converters: topologies, circuits, and control techniques. - Applications for energy conversion. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210120 | Advanced Supply Chain Design and Management | Semester 2 | Advanced models for supply chain design and management Coordination in supply networks |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210033 | Methods for the calculation and design of structures (DECI) | Semester 1 | Dynamic structural design. Nonlinear behavior. Various types of buckling in elements and structures. Buckling modes. Finite elements: dynamics and geometric nonlinearities. Design and design of bar structures under dynamic loads. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210039 | Robotics (AR) | Semester 1 | Introduction to Robotics. Robot Programming. Robot Modeling. Robot Control. Robot Applications. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270030 | Project management | Semester 2 | Quantitative project management techniques. Project selection and evaluation. Project portfolio management. Planning, organization, direction and control of engineering projects. BLOCK 1. PROJECT MANAGEMENT: INTRODUCTION. BLOCK 2. TIME MANAGEMENT. BLOCK 3. COST MANAGEMENT. BLOCK 4. BASIC KNOWLEDGE. EARNED VALUE ANALYSIS. BLOCK 5. RISK MANAGEMENT. BLOCK 6. MISCELLANEOUS PROJECT MANAGEMENT. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270032 | Maintenance Management Systems | Semester 2 | PART 1. Introduction and objectives of maintenance management systems; PART 2. Information and measurement systems in maintenance management; PART 3. Methods and techniques for continual maintenance improvement; PART 4. Methods and techniques for managing maintenance resources; PART 5. Methods for optimizing maintenance strategies. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560059 | Sustainable Electrical Systems | Semester 2 | Distributed renewable generation. Electric vehicles. Storage. Self-consumption. LV sustainable electrical installation projects. |
| M181 | Master's Degree in Chemical Engineering | 51810015 | Operation and Control of Chemical Plants | Semester 2 | Chemical Plant Operations Plant-wide Control |
| M190 | Master's Degree in Civil Engineering (2019) | 51900029 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 199 | Degree in Telecommunications Technology Engineering | 1990057 | Audiovisual production | Semester 2 | Description of the systems that make up an audiovisual production center. Basic audio and video equipment, formats, connections, lighting. Outdoor production and mobile units. |
| 199 | Degree in Telecommunications Technology Engineering | 1990070 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| 199 | Degree in Telecommunications Technology Engineering | 1990083 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| 199 | Degree in Telecommunications Technology Engineering | 1990055 | Noise Measures and Legislation | Semester 1 | Noise and vibration analysis and control. Environmental acoustics. Instrumentation (sound level meters, noise generators, etc.). Room acoustics. Diffuse sound field. Reverberation. Absorption. |
| 199 | Degree in Telecommunications Technology Engineering | 1990010 | Circuit theory | Semester 2 | Basic concepts and theorems of electrical circuits. Permanent sinusoidal regime. RLC circuits. Quadrupoles. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930040 | Air Pollution Engineering | Semester 1 | Analysis of industrial emissions. Definition of BACT. Applications of abatement techniques. Cross-media effects. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210059 | Thermal Turbomachines | Semester 2 | I INTRODUCTION TO THERMAL TURBOMACHINES II BLADE CASCADES III AXIAL TURBOMACHINES IV RADIAL TURBOMACHINES V SIMILARITY ANALYSIS VI OFF-DESIGN OPERATION OF TURBOMACHINES |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320026 | Aeronautical manufacturing processes | Semester 1 | BLOCK I: Basis for the Analysis of Forming Processes . Plastic Forming. Machining. BLOCK II: Design for Manufacturing and Assembly (DFMA). DFM for Consolidation, Plastic Deformation, and Machining Processes. Design for Assembly (DFA). BLOCK III: Non-Conventional Forming Processes . Advanced Machining Processes. Additive Manufacturing. Processes and Applications. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210101 | Energy Storage Systems | Semester 2 | Introduction to energy storage systems. Storage in power generation systems. Storage for thermal processes. Includes: 1. Introduction to energy storage . 2. Fundamentals of storage systems. 3. Types of storage: thermal, electrochemical, electrical, and mechanical. 4. Storage applications: generation, industry, residential/utilities, and transportation. 5. Value chain analysis and investment valuation. |
| 225 | Degree in Civil Engineering | 2250074 | Coastal and Fluvial Engineering | Semester 2 | River engineering. Ecology and ecosystems. Environmental pollution. Environmental factors affected by hydraulic works. Landscape and environmental assessment in hydraulic works. Integrated planning and management of water territories. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560015 | Statistics and Operations Research | Semester 1 | Probability Theory. Random Variables and Their Distributions. Sampling and Estimation. Hypothesis Testing. Statistical Software Package. Linear Programming. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210003 | Mathematics I | Semester 1 | Topic 1.- Complex numbers. Polynomials. Topic 2.- Matrices, determinants and systems of linear equations. Topic 3.- Vector spaces. Linear transformations. Topic 4.- Diagonalization of endomorphisms. Topic 5.- Euclidean and unitary vector spaces. Topic 6.- Real symmetric matrices and quadratic forms. Topic 7.- Euclidean affine space. Motions. Conics and quadrics. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630016 | Intelligent Maintenance Systems | Semester 2 | Advanced systems and techniques to support (and optimize) maintenance management and the management of the resources required for its execution |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040015 | IoT applications | Semester 1 | I - Introduction to IoT applications. II - Management, sensors, and programming of IoT devices. III - Programming artificial intelligence algorithms on IoT devices. III - Applications on IoT devices. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210099 | Selection of Materials and Processes (IRM) | Semester 1 | Primary selection using Ashby's method. Selection with conflicting objectives. Practical cases. |
| M143 | Master's Degree in Aeronautical Engineering | 51430009 | Air Navigation and Air Traffic Management | Semester 2 | Air Navigation: 1 Introduction to Air Navigation. Basic concepts. Effect of wind. 2 Models of the Earth's surface. Geodesy and cartography. Air routes. 3 Flight instruments. Altimetry and anemometry. 4 Route planning. Aeronautical charts. 5 Navigation based on radio aids. 6 Navigation equations. 7 Dead reckoning system. Inertial navigation. Errors. 8 Positioning-based navigation system. Satellite navigation. Errors. 9 Integrated navigation systems. Air Traffic Management: 1 Introduction. 2 Air traffic services. 3 Airspace management. 4 Slot allocation and flight plans. 5 Air traffic flow management. |
| M181 | Master's Degree in Chemical Engineering | 51810005 | Design of Water Treatment Plants | Semester 1 | Water purification methods. Drinking water treatment. Water treatment plant calculations. Management and operation of water treatment systems. Water disposal and reuse. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270007 | Statistics and Operations Research | Semester 2 | Statistics and Optimization. |
| M181 | Master's Degree in Chemical Engineering | 51810011 | Reactor Engineering | Semester 2 | Multiphase reactors. Fixed-bed catalytic reactors. Fluidized-bed reactors. Three-phase reactors |
| M143 | Master's Degree in Aeronautical Engineering | 51430031 | Aircraft path optimization | Semester 2 | Trajectory optimization techniques. Vertical profile optimization. Horizontal profile optimization. Complete trajectory optimization. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930036 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320016 | Aeronautical Organization and Air Transportation | Semester 2 | MAINTENANCE: -Terminology -Management model -Criticality -RCM/MSG3 -Resource Management - Indicators INTERNATIONAL STANDARDS AND ORGANIZATIONS CIVIL AVIATION ADMINISTRATION AIRPORTS TERMINALS |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320019 | Space Vehicle Systems | Semester 1 | Space Environment. Mission Analysis. Launch Systems. Orbit Control System. Power System. Thermal Control System. Communications System. Configuration and Structure System |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980035 | Efficient Design in Water Desalination Facilities | Semester 2 | BLOCK I: BASIC CONCEPTS OF DESIGN, OPERATION AND MODELING OF REVERSE OSMOSIS (RO) DESALINATION SYSTEMS (4 weeks) Chapter 1. INTRODUCTION TO WATER DESALINATION. Chapter 2. INTRODUCTION TO MODELING OF REVERSE OSMOSIS DESALINATION SYSTEMS. Chapter 3. MODELING OF RO DESALINATION SYSTEMS. Chapter 4. INTRODUCTION TO THE DESIGN OF WATER DESALINATION FACILITIES. BLOCK II: MODERNIZATION OF EXISTING RO PLANTS (1 week) Chapter 5. DESIGN PROBLEMS APPLIED TO MODERNIZATION OF RO PLANTS. BLOCK III: PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY (3 weeks) Chapter 6. BASIC CONCEPTS ON THE DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 7. PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 8. COUPLING OF PHOTOVOLTAIC SYSTEMS TO PUMPING SYSTEMS. BLOCK IV: PRE-DESIGN OF WATER DESALINATION INSTALLATIONS IN INDUSTRIAL APPLICATIONS (2 weeks) Chapter 9. PRE-DESIGN OF DESALINATION INSTALLATIONS FOR HYDROGEN PRODUCTION. Chapter 10. PRE-DESIGN OF DESALINATION INSTALLATIONS INTEGRATED IN POWER PRODUCTION PLANTS. BLOCK VI: INTRODUCTION TO RESEARCH (1 week) Chapter 11. RESEARCH IN REVERSE OSMOSIS PLANTS; PROCESSES IN DEVELOPMENT. BLOCK VII: PRACTICAL DESIGN CASES (2 weeks) Chapter 12. PRACTICAL DESIGN CASES IN VARIOUS GEOGRAPHICAL LOCATIONS Chapter 13. PRACTICAL DESIGN CASES FOR VARIOUS APPLICATIONS. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990003 | Design of Water Treatment Plants | Semester 1 | Water purification methods. Drinking water treatment. Water treatment plant calculations. Management and operation of water treatment systems. Water disposal and reuse. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990013 | Work Organization | Semester 2 | |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210035 | Business Planning and Management | Semester 1 | Business Analysis and Control Systems. Financial and Cost Accounting. Quality Management Systems. |
| 225 | Degree in Civil Engineering | 2250052 | Terminals and Interchanges | Semester 2 | Urban, metropolitan, and guided systems. Parking. Urban transport. Terminal types: modal, intermodal; passenger, freight; logistics centers. Parking. Operations and capacity. Congestion management. Simulation and modeling. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210029 | Metallic and composite materials (IRM) | Semester 1 | BLOCK 1: HEAT TREATMENTS OF STEEL Topic 1. IRON-CEMENTITE META-STABLE DIAGRAM. Topic 2. ANNEALING AND NORMALIZING TREATMENTS. Topic 3. AUSTENITE TRANSFORMATION. Topic 4. STEEL HARDENING. Topic 5. SPECIAL HEAT TREATMENTS. Topic 6. SURFACE HARDENING. BLOCK 2: FERROUS MATERIALS Topic 7. CONVENTIONAL STEELS I. Topic 8. CONVENTIONAL STEELS II. Topic 9. CONVENTIONAL STEELS III. Topic 10. ADVANCED STEELS. AUTOMOTIVE STEELS. Topic 11. FERROUS CASTINGS. BLOCK 3: NON-FERROUS METALLIC MATERIALS Topic 12. COPPER AND ITS ALLOYS. Topic 13. LIGHT ALLOYS. ALUMINUM Topic 14. LIGHT ALLOYS. TITANIUM Topic 15. LIGHT ALLOYS. MAGNESIUM Topic 16. NICKEL Topic 17. ZINC Topic 18. REFRACTORY METALS BLOCK 4: METAL MATRIX COMPOSITE MATERIALS Topic 19. TYPES OF MATRICES AND REINFORCEMENTS. APPLICATIONS. Topic 20. PRODUCTION METHODS. BLOCK 5: SELECTION OF MATERIALS AND PROCESSES Topic 21. SELECTION OF MATERIALS I Topic 22. SELECTION OF MATERIALS II BLOCK 6: LABORATORY PRACTICES |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280061 | Electronic Instrumentation and Control | Semester 2 | Ability to design instrumentation systems for testing and measurement. Ability to design instrumentation systems for control. Knowledge of commercial instrumentation subsystems and their connections. Knowledge of noise and interference sources in electronic circuits and appropriate design techniques to minimize them. Ability to design electronic circuits with analog, digital, and power components. Knowledge of micro- and nano-electronic design. Knowledge of commercial resources available for the development of electronic systems. Knowledge of electronic circuit design tools. Ability to design signal conditioning circuits for common sensors in the field of measurement and control systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210059 | Integral cycle of industrial plants | Semester 2 | Industrial plants, processes in industrial plants, design and construction, installations, plant conversion, municipal services, industrial plant valuation. |
| M143 | Master's Degree in Aeronautical Engineering | 51430010 | Aeronautical Organization and Air Transportation | Semester 2 | MAINTENANCE: -Terminology -Management model -Criticality -RCM/MSG3 -Resource Management - Indicators INTERNATIONAL STANDARDS AND ORGANIZATIONS CIVIL AVIATION ADMINISTRATION AIRPORTS TERMINALS |
| M143 | Master's Degree in Aeronautical Engineering | 51430056 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| 197 | Degree in Aerospace Engineering | 1970069 | Computational Mathematics | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| 197 | Degree in Aerospace Engineering | 1970030 | Wave Propagation and Electromagnetic Compatibility | Semester 2 | Electromagnetic Compatibility. Radiation and Wave Propagation. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830001 | Life cycle analysis | Semester 1 | Block 0: PROJECT Block 1. INTRODUCTION AND APPLICABLE REGULATIONS FOR LCA Block 2. LCA METHODOLOGIES. PHASES OF A LCA Block 3. TOOLS FOR LCA PREPARATION: DATABASES AND PROGRAMS Block 4. PRACTICAL CASES AND EXAMPLES OF LCAs |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630009 | Industrial Innovation and Prevention | Semester 2 | INDUSTRIAL PREVENTION BLOCK I. Legislative bases of Occupational Risk Prevention BLOCK II. General introduction to Safety BLOCK III. General introduction to Industrial Hygiene BLOCK IV. General introduction to Ergonomics and Applied Psychosociology BLOCK V. Management tools and practical applications INNOVATION BLOCK VI. CONCEPT OF INNOVATION BLOCK VII. INTRODUCTION TO VALUE ANALYSIS BLOCK VIII. IDENTIFICATION, CHARACTERIZATION AND DEFINITION OF VALUE ANALYSIS PROJECTS BLOCK IX. CUSTOMER AND COST ANALYSIS BLOCK X. FUNCTIONAL ANALYSIS BLOCK XI. MULTICRITERIA ANALYSIS |
| 199 | Degree in Telecommunications Technology Engineering | 1990005 | Mathematics II | Semester 1 | Differential and integral calculus. |
| 199 | Degree in Telecommunications Technology Engineering | 1990063 | Radio Communication Systems | Semester 1 | Design, deploy, organize, operate, and manage radiocommunication networks, systems, services, and infrastructures such as fixed service radio links, mobile communications, satellite communications, broadcasting, and other radiocommunication systems for radiodetermination. |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950005 | Integrated Design of Processes and Products | Semester 1 | The course consists of two thematic blocks: 1. Process Synthesis Block. This block focuses primarily on the Hierarchical Method for Synthesis of continuous chemical processes. It includes the analysis and design of reaction and separation systems, as well as the recirculation system between the two. 2. Process Integration Block. This block includes methods and techniques based on pinch analysis to achieve energy-efficient design of chemical processes. It addresses the design of heat exchange networks with criteria of maximum energy recovery and economic cost. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280011 | Mathematics Extension | Semester 1 | Thematic block 1. Analysis in a complex variable. ¿ Functions of a complex variable. ¿ Complex integration. ¿ Residue theory and applications. Thematic block 2. Transforms. ¿ Laplace transform. ¿ Fourier transform. ¿ Application of the Laplace and Fourier transforms. Thematic block 3. Numerical methods. ¿ Solving algebraic equations and systems. ¿ Interpolation and approximation. ¿ Differentiation and integration formulas. Thematic block 4. Extension of ODEs, systems and PDEs. Numerical resolution. ¿ Numerical methods: Euler, Runge-Kutta. ¿ Finite differences and finite elements. |
| 197 | Degree in Aerospace Engineering | 1970008 | Introduction to Aerospace Engineering | Semester 2 | - Aircraft. - Spacecraft. - On-board equipment and systems. - Airspace. - Air transport infrastructure. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280021 | Computer Control | Semester 1 | CONTENTS: Modeling of dynamic systems. Analysis of linear systems. Design and implementation of basic control systems. Practical control applications. Computer control. Industrial control techniques. Practical applications of computer control. Linear digital systems and related functions and transforms, and their application to engineering problems. |
| 199 | Degree in Telecommunications Technology Engineering | 1990034 | Fundamentals of Optical Communications | Semester 2 | Optical devices. Circuits and subsystems. Optical transmission equipment and systems. Specifications. |
| 199 | Degree in Telecommunications Technology Engineering | 1990082 | Computational Mathematics | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| M164 | Master's Degree in Electrical Energy Systems | 51640006 | Renewable Electricity Generation | Semester 1 | TOPIC 1: INTRODUCTION TOPIC 2: MINI-HYDRAULIC POWER PLANTS. - General characteristics. - Configuration of a mini-hydropower plant. - Components. - Turbine selection. Head. - Flow. - Feasibility study. Typical installations. - Electrical diagram. TOPIC 3: MARINE ENERGY - Wave power systems. - Tidal power. - Ocean currents TOPIC 4: WIND FARMS. - Wind characterization. - Types of turbines. - Types of wind turbines. - Wind resource assessment: wakes, electrical losses and unavailability - Wind power plant cost model: Investment and operating costs - Optimization of wind power plant configuration - Risk and sensitivity to parameters - Repowering TOPIC 5: SOLAR THERMOSATOR INSTALLATIONS TOPIC 6 PHOTOVOLTAIC INSTALLATIONS. - Solar radiation characterization. - Solar cells. - Solar module. - Photovoltaic installation. - Sizing of isolated installations. - Sizing of installations connected to the grid. TOPIC 7: STORAGE TECHNOLOGIES TOPIC 8: CONNECTION REQUIREMENTS. GRID CODES TOPIC 9: SOCIAL AND HEALTH IMPLICATIONS: BENEFITS OF RENEWABLE ENERGY, ENERGY EFFICIENCY AND SELF-CONSUMPTION. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270010 | Mathematics III | Semester 2 | Lesson 1. Functions of several variables. Differentiability. Scalar and vector fields. Limits and continuity. Partial derivatives and directional derivatives. Differentiability of scalar and vector fields: gradient vector and Jacobian matrix. Higher-order derivatives. Implicit differentiation and implicit function theorem. Lesson 2. Optimization of scalar fields. Quadratic forms and real symmetric matrices. Relative extrema of scalar fields. Absolute extrema of scalar fields. Lagrange multipliers. Lesson 3. Differential geometry. Regular curves. Frenet trihedron. Parameterized surfaces. First and second fundamental forms. Curvatures. Lesson 4. Multiple integrals. Double integrals. Change of variables: polar coordinates. Triple integrals. Change of variables: cylindrical and spherical coordinates. Lesson 5. Line integrals. Line integral. Conservative fields. Potential. Curl. Exact differential equations. Vector calculus in the plane: Green's theorem. Lesson 6. Surface integrals. Surface integrals. Divergence. Vector calculus in space: Stokes's theorem and Gauss's theorem. Lesson 7. Partial differential equations. Introduction. First-order partial differential equations. Laplace's, wave, and heat equations. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280042 | Industrial Computing | Semester 1 | Real-Time Computer Systems. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990016 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| 208 | Degree in Chemical Engineering | 2080044 | Waste Management and Treatment | Semester 1 | Waste characterization and management study. Waste treatment techniques. Landfill Chapter I. Waste. Introduction. General problems Chapter II. Legislation Chapter III. Urban waste management and collection systems Chapter IV. Material processing and separation technologies Chapter V. Biological waste treatment. Composting Chapter VI. Hazardous waste management and characterization Chapter VII. Stabilization/Solidification treatments Chapter VIII. Thermal treatments. Incineration Chapter IX. Remediation of contaminated soils Chapter X. Waste landfill Chapter XI. Radioactive waste management Chapter XII. Special waste management |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210024 | Structural engineering | Semester 2 | The course curriculum is organized into two blocks. The first focuses on knowledge of structural design tools, while the second focuses on the study of steel structures. Block 1: + General concepts of structural design: structural types, principles, and calculation assumptions + Matrix design of structures. Finite element method for bar structures. Block 2: + Steel structures. Basic concepts for design, design, and sizing according to current regulations. |
| M146 | Master's Degree in Industrial Engineering | 51460094 | Optimization and Control in Energy Systems | Semester 2 | Common thermal processes. Dynamic analysis. Process controllability. Optimization and control. |
| M181 | Master's Degree in Chemical Engineering | 51810020 | Advanced Simulation of Chemical Processes | Semester 2 | The subject is divided into two thematic blocks, each one related to the two types of tools or approaches to process simulation in chemical engineering: Block 1: Steady-state process simulation with commercial simulators Block 2: Analysis and design of process equipment using CFD simulation The first block will explain the functionalities and general characteristics of process simulators and those of the simulator selected for the subject. Aspects such as property calculation, selection and adjustment of thermodynamic methods, process unit models, convergence strategies, analysis tools and energy integration will be addressed. The second block will explain the fundamentals and methodologies for solving engineering problems using CFD techniques. The main objective of this part is to learn how to use a commercial CFD program in user mode, although an introduction to the bases and fundamentals of calculation will be made to understand the numerical methods and resolution schemes used by a commercial CFD simulator. Likewise, emphasis will be placed on understanding the structure of the conservation equations that govern the problems, the specific sub-models to be implemented in each particular case, their dominant parameters and the importance of creating an adequate mesh, applying the appropriate boundary conditions to the computational domains and performing a critical analysis of the solution. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210102 | Business Management Systems | Semester 2 | Cost accounting and budget control in different areas of the company. T1. Purchasing and Supplier Management. T2. Production - Manufacturing. T3. Sales Department. T4. Sales Margins. Sales Volumes. T5. Cost Structure. Results. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960043 | Modeling and Optimization of Management Problems | Semester 2 | Subject descriptors: - Operations research. - Artificial intelligence applied to industrial management problems. - Optimization in Project Management. Thematic blocks: BLOCK 1: Modeling management problems. BLOCK 2: Optimization of management problems and project management. BLOCK 3: Artificial intelligence applied to industrial management problems. BLOCK 4: Project development and management. Coding of models and resolution methods. |
| 208 | Degree in Chemical Engineering | 2080002 | Computing | TO | THEMATIC BLOCK 1: COMPUTER FUNDAMENTALS. THEMATIC BLOCK 2: ALGORITHMS. THEMATIC BLOCK 3: PROGRAMMING FUNDAMENTALS. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970033 | Quality and Efficiency of the Electricity Supply | Semester 2 | Topic 1. Power Supply Quality. Topic 2. Power Interruptions. Topic 3. Long-Term Voltage Variations. Topic 4. Voltage Imbalance. Topic 5. Harmonics. Topic 6. Voltage Fluctuations. Topic 7. Voltage Dips. Topic 8. Transient Overvoltages. Topic 9. Power Quality Measurement. Topic 10. International Power Quality Regulations. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560007 | Fundamentals of Materials Science | Semester 2 | Block I Intimate structure of materials. The atomic scale of metallic, ceramic, molecular and polymeric materials. Crystalline imperfections. Block II Phase transformations. Equilibrium diagrams. Non-equilibrium aspects. Block III Mechanical, electrical, thermal, optical and magnetic properties of materials ________________________________________ Detailed content by topic: 1. Introduction. 1.1. Exposition of the subject content, its standards and available material. Guidelines for the study of the subject 1.2. Materials in history and their importance. 1.3. Materials Science and Engineering. 1.4. Internal structure, properties and processing. 1.5. Behaviour in service and impact on the economy. 1.6. Classical classification of materials. New materials. 1.7. New trends in materials science Block I. Internal structure of materials. 2. Crystalline structure. 2.1. Short and long range order. Crystalline and amorphous structures. 2.2. Unit cell and crystal systems. 2.3. Crystallographic notation, Miller indices. 2.4. Characteristics of crystal structures. 2.4.1. Coordination number 2.4.2. Atomic radius 2.4.3. Packing factor 2.4.4. Bulk, linear, and surface densities. 2.4.5. Interstices. 3. Structures of metallic materials. 3.1. CCI structure. 3.2. CCC structure. 3.3. HC structure. 3.4. Stacking of close-packed planes in CCC and HC structures. 3.5. Slip systems. 3.6. Solid solutions. 3.6.1. Substitutional solutions. 3.6.2. Interstitial solutions. 3.6.3. Hume-Rothery rules. 3.7. Intermediate compounds. 3.8. Single and polycrystals. Allotropy. 3.9. Amorphous metals. 4. Crystal structures of ionic compounds: ceramic materials. 4.1. Coordination and ionic radius. 4.2. AX-type structures. 4.2.1. CsCl. 4.2.2. NaCl. 4.2.3. ZnS. 4.3. Ceramic glasses. 5. Covalent solids. 5.1.1. Diamond structure. 5.1.2. Structures of graphite, graphene, carbon nanotubes and fullerenes. 6. Polymeric materials. 6.1. Introduction. 6.2. Polymerization. 6.2.1. Average molecular mass. Mass and number fraction. 6.2.2. Degree of polymerization. 6.2.3. Polydispersity. 6.2.4. Additives 6.3. Molecular structure. 6.3.1. Linear polymers. 6.3.2. Branched polymers. 6.3.3. Cross-linked polymers. 6.3.4. Cross-linked polymers. 6.3.4.1. Vulcanization. 6.4. Isomerism. 6.4.1. Stereoisomerism: Isotactic, syndiotactic, and atactic polymers. 6.4.2. Geometrical isomerism: cis and trans isomers. 6.5. Crystallinity: degree of crystallinity, micelles, and spherulites. 6.6. Types of polymers: thermoplastics, thermosets, and elastomers. 7. Lattice imperfections and diffusion. 7.1. Introduction. 7.2. Point defects. 7.2.1. Vacancies. 7.2.2. Interstitial atoms. 7.2.3. Substitutional atoms. 7.2.4. Frenkel defects. 7.2.5. Schottky defects. 7.2.6. Defects due to lack of stoichiometry. 7.3. Linear defects: dislocations. 7.3.1. Wedge, helical and mixed dislocations. 7.3.2. Burgers vector. 7.4. Surface defects. 7.5 Diffusion. 7.5.1. Fick's laws. 7.5.2. Diffusion modes. 7.5.3. Atomic mechanisms of diffusion in volume. 7.5.4. Applications Block II. Development of microstructures and phases. 8. Phase transformations. 8.1. Introduction: Phase and components. 8.2. LS transformation: Solidification. 8.3. Phases and microconstituents. 9. Introduction: Steels and castings. 9.1. Phases and microconstituents. 9.2. Typical microstructures of hypoeutectoid, eutectoid, and hypereutectoid steels. 9.3. Heat treatments. 9.4. Annealing. 9.5. Normalizing. 9.6. Hardening and quenching. Block III. Properties of materials. 10. Mechanical properties of metals. 10.1. Introduction. 10.2. Elastic behavior. 10.2.1. Modulus of elasticity 10.2.2. Yield strength. 10.2.3. Proportional limit. 10.2.4. Poison's ratio 10.3. Plastic deformation. 10.3.1. Tensile strength. 10.3.2. Creep. 10.3.3. True stress-strain curve 10.4. Ductility and toughness. 11. Electrical properties of materials. 11.1. Electrical conductivity. 11.1.1. Band theory: conductors, semiconductors, and insulators. 11.2. Conductors. 11.2.1. Temperature dependence of conductivity. 11.2.2. Alloy dependence of conductivity. 11.3. Semiconductors. 11.3.1. Intrinsic and extrinsic semiconductors. 11.3.2. Temperature dependence of conductivity. 11.4. Ionic conductivity. 12. Magnetic properties of materials. 12.1. Basic concepts. 12.2. Origin of magnetic moments. 12.3. Ferromagnetism, paramagnetism, and diamagnetism. 12.4. Hysteresis: Hard and soft magnetic materials. 13. Thermal properties of materials. 13.1. Heat capacity. 13.1.1. Variation with temperature. Debye temperature. 13.2. Thermal conductivity. 13.3. Thermal expansion. 13.4. Thermal stresses. 13.5. Thermal shock. 14. Optical properties of materials. 14.1. Interactions of light with matter. 14.2. Optical properties of metals. 14.3. Optical properties of non-metallic materials: refraction, reflection, absorption, transmission, color. 15. Corrosion. 15.1. Introduction. 15.2. Theoretical bases of aqueous corrosion. 15.2.1. Definition of cathodes and anodes. 15.2.2. Electrochemical potentials. 15.3. Types of corrosion cells. 15.3.1.1. Galvanic. 15.3.1.2. Concentration. 15.3.1.3. Differential aeration. 15.4. Electrochemical and galvanic series. 15.5. Corrosion rate. Passivation. PRACTICES: 1. Crystal structures. 2. Metallographic preparation. Determination of grain size. 3. Determination of material hardness. 4. Impact behavior by Charpy testing and tensile curves. 5. Optical microscopy. |
| M146 | Master's Degree in Industrial Engineering | 51460084 | Intelligent Maintenance Systems | Semester 2 | Advanced systems and techniques to support (and optimize) maintenance management and the management of the resources required for its execution |
| M146 | Master's Degree in Industrial Engineering | 51460048 | Transient and Dynamic Analysis of Electrical Systems | Semester 2 | Block 1. Electromagnetic Systems Topic 1.1: Introduction to transient phenomena in electrical systems Topic 1.2: Transients in power lines Topic 1.3: Case studies Block 2. Electromechanical Systems Topic 2.1: Electromechanical modeling of synchronous machines Topic 2.2: Generator controller modeling (AVR, GOV and PSS) Topic 2.3: Differential/Algebraic Systems and their analysis Topic 2.4: Power-frequency inertial response Topic 2.5: Transient stability |
| 208 | Degree in Chemical Engineering | 2080026 | Basic Operations with Solids and Fluids | TO | TOPIC 1.- PROPERTIES OF GRANULATED SOLIDS TOPIC 2.- STORAGE AND TRANSPORT OF SOLIDS TOPIC 3.- SIEVING TOPIC 4.- SIZE REDUCTION TOPIC 5.- CIRCULATION OF FLUIDS IN DUCTS TOPIC 6.- IMPULSION OF LIQUIDS TOPIC 7.- IMPULSION OF GASES TOPIC 8.- AGITATION TOPIC 9.- MOVEMENT OF PARTICLES WITHIN FLUIDS TOPIC 10.- CLASSIFICATION AND SEPARATION OF SOLIDS TOPIC 11.- CIRCULATION OF FLUIDS THROUGH POROUS MEDIA TOPIC 12.- FILTRATION TOPIC 13.- FLUID DYNAMIC DESIGN OF PACKED TOWERS TOPIC 14.- FLUIDIFICATION |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210024 | Integration of Renewable Energy | Semester 1 | Integration of electronic devices into electrical networks, storage system management, energy efficiency, wave quality, direct current transmission. |
| 208 | Degree in Chemical Engineering | 2080036 | Separation Operations | TO | Operations controlled by mass transfer, momentum transfer, and heat transfer |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990008 | Air Pollution Engineering | Semester 1 | Analysis of industrial emissions. Definition of BACT. Applications of abatement techniques. Cross-media effects. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040001 | Multidisciplinary applications of ICT | TO | Block 1: Introduction to Multidisciplinary Applications Block 2: Multidisciplinary Applications related to Signal Theory and Communications Block 3: Multidisciplinary Applications related to Telematics Engineering Block 4: Multidisciplinary Applications related to Electronic Engineering Block 5: Integration of ICTs in multidisciplinary contexts |
| 225 | Degree in Civil Engineering | 2250027 | Civil and Environmental Engineering | Semester 1 | Environmental impact study and assessment. Environmental impact statement. |
| 225 | Degree in Civil Engineering | 2250001 | Company | Semester 1 | Adequate understanding of the concept of business, the institutional and legal framework of business, and business organization and management. |
| 225 | Degree in Civil Engineering | 2250016 | Soil and Rock Mechanics | Semester 2 | Elementary properties of soils and rocks. Classifications. Laboratory and in situ tests. Water flow in the ground. Compressibility and consolidation. Strength. Geomechanical classifications of rocks. Rheological models of soils and rocks. Partially saturated soils: soil compaction, concepts of expansiveness and collapse. Land survey. Regulations. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210014 | Concrete Structures (DECI) | Semester 1 | Typology, materials, regulations, and design bases for reinforced and solid concrete structures. Safety and strength verification criteria. Fitness for service. Durability of structural concrete. Sizing of structural elements. Quality control in concrete structures. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280071 | Robotics and Automation | Semester 2 | Robot control architecture. Robot control methods. Advanced programming. Real-time computing systems. Industrial communications systems. Monitoring systems. Modeling and automation of production systems. Computer-aided manufacturing. Automation projects. Electronic systems for automation and control. Embedded systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560009 | Chemistry | Semester 1 | Basic concepts of Chemistry. Kinetics, Thermodynamics and Equilibrium. Chemistry applied to engineering. CHAPTER I. INTRODUCTION TOPIC 1. BASES OF CHEMISTRY. STOICHIOMETRY TOPIC 2. THERMOCHEMISTRY. ENERGY CHANGES IN CHEMICAL REACTIONS CHAPTER II. STATES OF MATTER TOPIC 3. GENERAL PROPERTIES AND STATES OF MATTER TOPIC 4. GASES TOPIC 5. LIQUIDS AND SOLUTIONS CHAPTER III. CHEMICAL CHANGE. EQUILIBRIA TOPIC 6. CHEMICAL KINETICS. REACTION RATE TOPIC 7. SPONTANEITY AND CHEMICAL EQUILIBRIUM TOPIC 8. EQUILIBRIA IN AQUEOUS SOLUTION |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560034 | Design and Project of Structures for Industry | Semester 2 | Safety criteria, loading actions and assumptions, materials. Introduction to steel structure design: Limit States. Applicable regulations. Common structural typologies in the industry. Industrial structural design. Detailed engineering. |
| M181 | Master's Degree in Chemical Engineering | 51810017 | Advanced Separation Processes | Semester 1 | Multicomponent distillation Adsorption and ion exchange systems Crystallization Membrane separation processes Non-conventional separation systems |
| 197 | Degree in Aerospace Engineering | 1970073 | Aerospace Engineering Projects | Semester 1 | Definition, content, and activities for project implementation. Applied knowledge for the development of aerospace engineering projects. Knowledge of specific aerospace engineering regulations. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600008 | Optimization and Control in Energy Systems | Semester 2 | Common thermal processes. Dynamic analysis. Process controllability. Optimization and control. |
| 197 | Degree in Aerospace Engineering | 1970031 | Propulsion Systems | Semester 1 | Propeller Propulsion Systems. Jet Aircraft Propulsion Systems. Space Propulsion Systems. |
| M181 | Master's Degree in Chemical Engineering | 51810031 | Environmental Quality Assessment | Semester 1 | - Sampling and analysis of environmental pollutants. - Automated methods for analyzing environmental pollutants. - Characterization and analysis of solid waste. |
| 203 | Degree in Industrial Technology Engineering | 2030148 | Simulation and Optimization of Chemical Processes | Semester 2 | - Chemical process simulation. - Commercial simulators. - Chemical process optimization and evaluation. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210018 | Environmental Management in Industry (DIS) | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. Analysis of climate change mitigation and adaptation in industry, and implications of the Sustainable Development Goals for the industry. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960045 | Advanced Production Systems | Semester 1 | Cellular manufacturing and sustainable manufacturing. Intelligent production planning, scheduling, and control systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210093 | Projects and Integrated Management of Works in Industrial Engineering | Semester 2 | PART 1: Design of industrial buildings and facilities. PART 2: Urban planning in industrial engineering and urban development and service projects in industrial and business parks and estates. PART 3: Integrated construction management. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960041 | Advanced Quantitative Management Methods | Semester 1 | The subject consists of two different modules: 1) Analysis of networks and complex systems 2) Cooperative games |
| 197 | Degree in Aerospace Engineering | 1970047 | Avionics | Semester 1 | Aircraft electronic systems. Flight control and engine control computers. Introduction to onboard software development. |
| 197 | Degree in Aerospace Engineering | 1970034 | Airport structures i | Semester 2 | Fundamentals of airport structure design and calculation. Dimensioning and cross-section verification. Sizing of structural elements. Materials and element types. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930043 | Numerical Methods in Chemical and Environmental Engineering | Semester 1 | Introduction to MATLAB and Numerical Analysis. Systems of linear equations. Interpolation. Nonlinear optimization and equation solving. Numerical methods for ordinary and partial differential equations. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830002 | Biorefineries | Semester 1 | The course is divided into four main sections that cover the following topics: - Fundamentals of Biorefineries: concepts, types, and platforms - Fundamentals of biomass transformation processes - Production of biofuels, biofuels, and bioproducts - Energy, economic, and environmental analysis of biorefineries. The first section develops the fundamental concepts of biorefineries, their classification and typology, the main processes that comprise them, experiences to date in Spain and around the world, etc. Likewise, the biomass resource, logistics, and the biomass market are studied. The second section studies biomass transformation processes, including physical and chemical pretreatment processes as well as thermochemical, biochemical, and hydrothermal conversion processes. The third section describes the production processes of biofuels (biofuels and chemicals) and bioproducts. Finally, the fourth section presents a detailed analysis of the different types of biorefineries, grouped into two large "families." thermochemical and biochemical, the different platforms that define the various biorefineries currently under development (lipids, sugars, biogas, proteins, synthesis gas, etc.) as well as an analysis of the energy and environmental efficiency of biorefineries. |
| 197 | Degree in Aerospace Engineering | 1970036 | Airport Management and Operation | Semester 2 | Understanding the unique nature of airport infrastructure, buildings, and operations, as well as their management, maintenance, design, and operation. Airport security and control plans. Environmental impact. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210057 | Thermoeconomics of Energy Systems | Semester 1 | Chapter 1: Thermodynamic functions of compound and reactive systems. Chapter 2: Thermodynamic analysis of industrial processes. Chapter 3: Introduction to energy systems design. Chapter 4: Documentation, writing, and presentation of technical reports. Chapter 5: Economic analysis of energy systems. Chapter 6: Thermoeconomic analysis and evaluation. Chapter 7: Introduction to life cycle analysis (LCA). Chapter 8: Thermoeconomic and life cycle analysis of energy sectors. Compulsory work: Documentation, writing, and presentation by groups of a preliminary technical report related to the subject. The subject is taught in Spanish. |
| 225 | Degree in Civil Engineering | 2250014 | Geology Applied to Civil Engineering | Semester 1 | BRIEF DESCRIPTION OF CONTENTS Petrology. Soil as a support for civil works. Terrain morphology. Influence of climatology on the morphology and behavior of the terrain. Slope instability. External and internal geodynamics. Structural geology. History and evolution of the Earth. Geological cartography. Geology applied to public works. Geology of Spain. Environmental geology. |
| 225 | Degree in Civil Engineering | 2250066 | Aesthetics of Civil Engineering | Semester 2 | Framing aesthetics as a discipline. ¿ General ambitions ¿ Subjectivism versus objectivity: the possibility of shared reflection ¿ Dimensions of the debate: a brief overview of the history of aesthetics. Situating the current position of civil engineering as an aesthetic creator and as a source for aesthetic reception. ¿ The arts of extension (architecture, civil engineering, urban planning, landscaping). ¿ Aesthetic particularities of civil works. ¿ Influence, transfers, and tensions between civil engineering and other arts: architecture, painting, sculpture, design. ¿ Distinction between project and work; creation and construction. Diachrony: show the mechanisms that, over time, add and subtract aesthetic value to the work: ¿ cultural and stylistic succession (fashions, learning and social forgetting) ¿ immersion in nature (weathering, growth) Study the dominant aesthetic characteristics of civil engineering through historical succession ¿ Greco-Roman world ¿ Middle Ages, first universities and scholasticism ¿ Renaissance and Enlightenment: scientific method, the first military engineering ¿ Industrial Revolution: advent of civil engineering (ponts et chaussées, école polytechnique¿) ¿ modernity and post-modernity Explore the aesthetic foundations of civil engineering ¿ composition ¿ form ¿ space ¿ circulation ¿ proportion scale ¿ organizing or structuring principles ¿ landscape framework Show the singularities and characteristics of the main manifestations of civil engineering. reflections on aesthetic ideas in project practice. Aesthetic notes on the monumental heritage of civil engineering ¿ Bridges and tunnels ¿ Transport networks (railway infrastructure, roads and highways) ¿ Hydraulic infrastructure (dams, pipelines) ¿ Ports and coastal infrastructure. An approach to Spanish civil engineering. The author and his work. ¿ Outstanding creations and debate raised ¿ A review of selected examples . Conclusions and sharing. Exercises and debate. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280035 | Expansion of Electronic Instrumentation | Semester 1 | Ability to design instrumentation systems for testing and measurement. Ability to design instrumentation systems for control. Knowledge of commercial subsystems for instrumentation and their connection. Knowledge of noise and interference sources in electronic circuits and appropriate design techniques to minimize them. Ability to design electronic circuits with analog, digital, and power components. Knowledge of micro and nano-electronic design. Knowledge of the technologies used to manufacture electronic circuits. Knowledge of commercial resources available for the manufacture of electronic systems. Knowledge of electronic circuit design tools. Ability to design signal conditioning circuits for common sensors in the field of measurement and control systems. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270036 | Industrial Reliability | Semester 1 | Reliability. Design of experiments. Design of robust production systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560025 | Materials Technologies | Semester 2 | Block I. Introduction. Material selection criteria. Processing-structure-properties relationship. General considerations: material families, processing types, and service conditions. Examples of practical application cases (there is no ideal material). Block II. Metallic alloys and their processing. Carbon steels and their heat treatments (mass and surface). Weakly alloyed, high-alloy, stainless, and tool steels. Metals with cryogenic applications and used at high temperatures. Ferrous castings. Fe-Gr versus Fe-Fe3C equilibrium diagram. Influence of the type of matrix and/or graphite on the properties of ferrous castings. Non-ferrous metallic materials, properties and applications: copper and its alloys; aluminum and its alloys; magnesium and its alloys. Examples of metallic superalloys. Molding and continuous casting. Suitability for molding. Physical and chemical heterogeneities. Plastic deformation (cold, warm, and hot drawing). Metal welding. Fusion and solid-state welding. Brazing and soldering. Metallurgical aspects and defects inherent in the welding process and the heat-affected zone. Conventional powder metallurgical processing (mechanical grinding, mixing, pressing, and sintering). Modern trends in powder metallurgy: MIM, directed freezing, electrical sintering, laser sintering or fusion, etc. Block III. Ceramic materials, processing, and applications. Glass, raw materials, and manufacturing processes. Relationship between properties and applications. Traditional ceramics and cements, raw materials, manufacturing process steps, properties, and applications. Advanced, functional, and structural ceramics. Applications and properties. Block IV. Polymers and their processing. Thermoplastics, thermosets, elastomers, and fibers. Influence of temperature and mechanical stress. Applications. Differences between polymers and commercial plastics, relationship between additives and material properties. Conventional polymer forming (extrusion, injection molding, thermoforming, etc.). More complex or advanced processes: co-extrusion, co-injection, and additive manufacturing (3D printing: FDM, FFF, etc.). Adhesive bonding or welding of plastic parts. Recycling and/or reuse of plastics. Block V. Composite materials and their processing. Types of composite materials based on their matrix (metal, ceramic, or polymer). Types of reinforcements (particles or fibers). Manufacturing processes, typical manufacturing defects, influence of reinforcement properties and compatibility with the matrix on the in-service behavior of the composite material. Examples of composite materials and their uses. Block VI. In-service behavior of parts, components, or structures. Mechanical behavior (tensile, compression, torsion, bending, and fatigue), concept of damage tolerance. Fracture resistance of brittle materials, application of Weibull statistics, concepts of failure probability. Design criteria: small elastic strains, yield strength, plastic collapse, fracture toughness, and failure analysis diagram. Hardening and fracture toughness increase mechanisms (R-curve). SN curves and Goodman diagram. Fatigue limit, strength, and sensitivity. Damage tolerance (kinetics of large crack growth propagation by phatic forces - Paris-Erdogan Law). Influence of notch sensitivity, surface finish, temperature, and environmental conditions. Thermomechanical behavior: viscoelasticity, thermocreep, and stress relaxation phenomena. Mechanisms responsible for creep, influence of grain size. Degradation of structural components under contact stresses (friction and wear). Mechanisms and types of wear. Wear prevention: lubrication and surface modification treatments. Degradation of polymers and ceramics, as well as corrosion of metallic materials in aggressive media. Mechanisms, types and actions for the prevention of corrosion phenomena. Practicals P1: In-Service Behaviour (2.5 h) Metallography of metals Effect of temperature on in-service behaviour: heat treatments, thermal shock Determination of mechanical properties: microhardness, fracture toughness¿ P2: Forensic Powder Metallurgy (2.5 h) Fundamentals of the manufacturing process for parts using metal powders: powder characterization, mixing, compaction and study of manufactured parts (porosity, image analysis) Comparison with other manufacturing techniques. P3: Forensic Engineering (2.5 h) Non-destructive testing (NDT): Physical principle, experimental procedure, as well as advantages and disadvantages of the most common techniques used to evaluate surface and/or internal defects. Failure analysis: principles and methodology of forensic engineering; fault diagnosis. Analysis of real cases of failure in service. Note: each professor, in addition to the generic real cases presented, may comment on some according to their scientific-technical and/or industrial experience |
| M143 | Master's Degree in Aeronautical Engineering | 51430027 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 197 | Degree in Aerospace Engineering | 1970054 | Airport Facilities | Semester 1 | Design, construction, and maintenance of airport facilities. The subject areas covered in this course are: IDA-1: AIRPORT WATER SUPPLY AND DRAINAGE SYSTEMS; IDA-2: FIRE PROTECTION; IDA-3: AIRPORT-SPECIFIC FACILITIES (Baggage Handling Systems; Ramp Fuel Supply Facilities); |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550009 | Materials Engineering | Semester 2 | BLOCK I: INTRODUCTION TO MATERIALS ENGINEERING Topic 1: Metallic Materials Topic 2: Ceramic Materials Topic 3: Polymeric Materials Topic 4: Composite Materials BLOCK II: MECHANICAL CHARACTERIZATION OF MATERIALS Topic 5.- Introduction to the characterization of materials Topic 6.- Characterization of metallic materials Topic 7.- Characterization of fiber-reinforced composite materials Topic 8.- Characterization of adhesives BLOCK III. POWDER METALLURGY Topic 9: Introduction and manufacture of powders. Topic 10: Powder metallurgical routes. Topic 11: Products and applications BLOCK IV: MAGNETIC MATERIALS Topic 12. Types of magnetic materials Topic 13. Hysteresis curve Topic 14. Hard magnetic materials Topic 15. Soft magnetic materials Topic 16. Market and potential applications BLOCK V: ENVIRONMENTAL DEGRADATION AND PROTECTION Topic 17: Oxidation and corrosion Topic 18: Corrosion prevention methods Topic 19. Wear Topic 20. Coatings Topic 21: Environmental degradation of ceramics and polymers BLOCK VI: MATERIALS SELECTION Topic 22. Industrial design Topic 23. Selection by the Asbhy method (I) Topic 24. Selection by the Asbhy method (II) |
| 197 | Degree in Aerospace Engineering | 1970020 | Mathematical methods | Semester 2 | Numerical linear algebra. Solving nonlinear equations and systems of equations. Interpolation. Numerical quadrature and differentiation. Numerical methods for differential equations and systems of equations. |
| M181 | Master's Degree in Chemical Engineering | 51810001 | Life cycle analysis | Semester 1 | Block 0: PROJECT Block 1. INTRODUCTION AND APPLICABLE REGULATIONS FOR LCA Block 2. LCA METHODOLOGIES. PHASES OF A LCA Block 3. TOOLS FOR LCA PREPARATION: DATABASES AND PROGRAMS Block 4. PRACTICAL CASES AND EXAMPLES OF LCAs |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920045 | Experimental Methods in Mechanical Engineering | Semester 1 | 1. DATA ACQUISITION Summary. Measurement equipment. Measurement chain. Uncertainty. Calibration. Data acquisition (cable connection, digital conversion, sample frequency, aliasing, leakage, filtering, windows). LabVIEW programming. Calibration of MEMS accelerometers and other applications. 2. INSTRUMENTATION AND EXTENSOMETRY Components in an instrumentation setup, experimental techniques and sensors in mechanical engineering. Extensometry. Application of wavelet transform in damage detection in structures. Machine testing and calibration. Displacement transducers. Extensometry setups in different equipment. Testing of a structure. 3. MACHINE TESTING Programming a servo hydraulic machine. Description of its components: hydraulic central and circuit, actuator, servo valve, controller, software, etc. Modes of testing and adjustment of parameters. Measurement equipment: LVDT, extensometer, load cell. Design of testing auxiliary equipment. Obtaining and processing the data. Testing of relaxation in a viscoelastic material. Creep compression test in a viscoelastic material. Cyclic dynamic testing in a cellular structure of a viscoelastic material (loss factor and dissipated energy). 4. CONCRETE TESTING Fracture mechanics applied to structural concrete. Normalized tests in concrete. Experimental determination of fracture behavior of structural concrete (fracture properties, size effect, applications). Influence of size and shape of specimens on the compression strength of concrete. Three point bend test controlling with CMOD. Determination of behavior curve stress-strain of concrete in cylindrical specimens. Work fracture test on a notch concrete specimen under RILEM procedure. Analysis of results. Determination of concrete properties. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960034 | Efficiency and productivity | Semester 2 | Efficiency analysis Productivity measurement Technological change in organizations Advanced data envelopment analysis methods Advanced multicriteria methods Advanced multiobjective optimization |
| 225 | Degree in Civil Engineering | 2250049 | Waterworks | Semester 1 | - Hydrologic cycle. - Hydrologic basin. - Hydrogeology, Groundwater harvesting techniques, Aquifer behavior models, Legal regulation of groundwater. - Dam typology, Design criteria, operation, conservation, rehabilitation, monitoring, safety. - Equations governing fluid movement. - Potential movements. - Boundary layer. - Turbulence. - Water harvesting and transport. - Irrigation. - Waterfalls: energy use, hydromechanical equipment. - Turbines, pumps. - River engineering. - Water resource availability, Integrated planning and management of water territories. - Water economy and productivity. - Ecology and ecosystems. - Environmental pollution. - Environmental factors affected by hydraulic works. - Landscape and environmental assessment in hydraulic works. - Design, operation, and maintenance of water supply, sanitation, and sewerage systems; legal regulations; sanitary engineering laboratory. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940046 | Electronic Systems for Renewable Energy Management | Semester 2 | Chapter I. Introduction to electronic systems for renewable energy management Chapter II. Wind energy Chapter III. Photovoltaic energy Chapter IV. FACTS systems, energy storage and electric vehicles |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210050 | Refrigeration technology (EN) | Semester 2 | Cold production systems. Refrigeration equipment technology. Food cooling and preservation. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270070 | Applied Optics | Semester 2 | Optical observation instruments. Photonics. Digital cameras. 2D and 3D visualization systems and techniques. Non-visible imaging systems. Optical technologies for engineering. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270019 | Chemical and Environmental Technology | Semester 2 | DESCRIPTORS: Basic principles of material and energy balances. Treatment technologies and characteristics of pollutant purification processes. Environmental legislation and management. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600002 | Industrial communications | Semester 1 | Thematic Blocks: Block 1. Signal Modulation in Communications. Block 2. Guided and Unguided Signal Propagation. Block 3. Fundamentals of Optical Communications. Block 4. Industrial Buses and Optical Sensor Networks. Block 5. Topologies and Links Used in Industrial Communication Networks. Block 6. Industrial Communication Networks. |
| 225 | Degree in Civil Engineering | 2250010 | Materials Chemistry | TO | CHAPTER I. INTRODUCTION TOPIC 1. INTRODUCTION. STOICHIOMETRY Approach to General Chemistry. Origins of atomic theory. Dalton's atom. The periodic table. Electron configurations. Periodic properties. Concept of mole. The chemical equation. Limiting reagent and yield. Stoichiometry in industry. Material balances CHAPTER II. EQUILIBRIA IN AQUEOUS SOLUTION TOPIC 2. SOLUBILITY AND PRECIPITATION Solubility and solubility product. Factors affecting solubility. Calculation of concentrations. Fractional precipitation. TOPIC 3. ACID-BASE EQUILIBRIA Concepts of acid and base. Acidic character. Action of water. pH. Couple strength: intervals of predominance and pH. Calculation of concentrations. Neutralization titrations. TOPIC 4. REDOX EQUILIBRIA Normal reduction potential. Electrochemical series. Nernst equation. Normal potential and equilibrium constant. Calculation of concentrations in redox equilibria. CHAPTER III. ATOMIC SCALE OF MATERIALS TOPIC 5. INTIMATE STRUCTURE OF MATERIALS Relationship between internal structure and properties. Interatomic forces. Bonds and types of materials. Order and disorder. Elementary cell and crystal systems. Crystallographic notation. Miller indices. Characteristics of a crystal structure. TOPIC 6. METALLIC MATERIALS Crystal structures of metals. Stacking of planes. Deformability. Slip systems. Solid solutions and metallic alloys. Hume-Rothery rules. Metallic glasses. TOPIC 7. CERAMIC MATERIALS Ionic compounds. Structure of diamond. Ceramic solid solutions. Silicates. Ceramic glasses. TOPIC 8. MOLECULAR MATERIALS Introduction. Molecular liquid solutions. Liquid crystals. Molecular gels. Molecular forms of carbon. TOPIC 9. POLYMERIC MATERIALS Definition of polymer. Polymerization. Degree of polymerization. Average molecular weight. Types of polymers. Thermoplastics. Elastomers. Thermosets. Polymeric solid solutions. Additives. Non-conventional polymers. TOPIC 10. CRYSTALLINE IMPERFETIONS Classification of defects. Volumetric, surface, linear and point defects. Diffusion. Deformation of metals. CHAPTER IV. MICROSCOPIC SCALE OF MATERIALS. TOPIC 11. EQUILIBRIUM DIAGRAMS Concept of system, components, phases and constituents. Phase rule. Unary, binary and ternary diagrams. Lever rule. Concept of invariant transformation. Eutectic, eutectoid, peritectic and peritectoid transformations. Diagrams with total solubility in liquid and solid states. Diagrams with total solubility in the liquid state and total insolubility in the solid state. Diagrams with total solubility in the liquid state and partial solubility in the solid state. TOPIC 12. EQUILIBRIUM DIAGRAMS OF TECHNOLOGICAL INTEREST ¿ STEELS AND CASTINGS Phase diagram of the Fe-C alloy. Steels and castings. Phases and microconstituents. Properties. Heat treatments of steels: annealing, normalizing and tempering. Main aluminum systems. CHAPTER V. PROPERTIES OF MATERIALS TOPIC 13. MECHANICAL PROPERTIES Introduction. Elastic deformation: Elasticity, yield strength. Plastic deformation: strength, ductility. Toughness. Impact resistance. Hardness. TOPIC 14. THERMAL PROPERTIES Heat conductivity. Expansion. Heat conduction mechanisms. Heat-induced mechanical stresses. TOPIC 15. CHEMICAL PROPERTIES Corrosion of metallic materials. Electrochemical considerations. Corrosion kinetics. Forms of corrosion. Corrosion prevention. Corrosion of ceramic materials. Degradation of polymeric materials. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280020 | Theory of Machines and Mechanisms | Semester 2 | Schematic representation of mechanisms. Introduction to the kinematic and dynamic analysis of mechanisms. Knowledge of the principles of machine and mechanism theory. Study and design of the motion of machines and mechanisms, with special attention to the motion of robots. |
| M143 | Master's Degree in Aeronautical Engineering | 51430019 | Advanced Avionics | Semester 1 | - Innovative technologies to optimize energy use in modern aircraft. - Introduction to new electrical power generation systems. Primary and secondary distribution. Electronic control. Electrical loads. Emergency power generation systems. Recent electrical system developments. - Warning, protection, and control systems. - New electromechanical actuators. - All-electric aircraft concept. - Aeronautical regulations applicable to the design of onboard electronic systems: DO-254, DO-178C. Certification of aeronautical systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210145 | Vehicle Control | Semester 2 | OBJECTIVES: Knowledge of automotive control systems. Knowledge of modeling for automotive control. Knowledge of control strategies for automotive propulsion and dynamics. COMPETENCES: Specific competencies: Systematic understanding of the engineering field related to Automation and Robotics. Mastery of the research skills and methods related to their area. Ability to apply knowledge to a wide range of industrial and economic sectors. Identification of faults and possible improvements in automated systems. Capacity for quantitative and qualitative analysis of the operation and improvements of processes. Development of mathematical models and simulation tools for the dynamic systems under study in the fields of Automation and Robotics. Ability to practice specific procedures in the analysis of dynamic systems and controller design. Generic competencies: Possess and understand knowledge that provides a basis or opportunity to be original in the development and/or application of ideas, often in a research context. That students are able to apply acquired knowledge and problem-solving skills in new or unfamiliar environments within broader (or multidisciplinary) contexts related to their area of study; That students are able to integrate knowledge and cope with the complexity of making judgments based on information that, while incomplete or limited, includes reflections on the social and ethical responsibilities associated with the application of their knowledge and judgments; That students are able to communicate their conclusions—and the knowledge and ultimate reasons that support them—to specialized and non-specialized audiences in a clear and unambiguous manner; That students possess the learning skills that allow them to continue their studies in a manner that will be largely self-directed or autonomous. Function effectively both individually and in teams. Use a variety of methods to communicate effectively with the engineering community and society at large. Demonstrate awareness of responsible engineering practice, social and environmental impact, and commitment to professional ethics, responsibility, and standards of engineering practice. Demonstrate awareness of business and project management practices, as well as risk management and control, and understand their limitations. Recognize the need for and have the ability to voluntarily engage in continuous learning. Function effectively as a team leader comprised of individuals from diverse disciplines and levels. Work and communicate effectively in national and international contexts. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900041 | Ports and Coasts | Semester 1 | Wave propagation processes, higher-order wave theories, random nature of irregular waves through spectral analysis. Port typology and port users. Port planning and design. Design of berthing and mooring structures. Turbulence and operation in basins. Maritime configuration: access channels and flotation areas. Spanish regulatory framework. ROM Program. The ship and the port. Dredging works. Environmental aspects. Sediment transport model. Radiation tensor. Beach nourishment. Design of coastal defense structures. Coastline evolution models. Coastal law |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630012 | Dynamic systems modeling | Semester 1 | I) Continuous simulation. II) Discrete event simulation. |
| 199 | Degree in Telecommunications Technology Engineering | 1990043 | Telecommunications Infrastructure Systems | Semester 2 | Reception and distribution of radio and television signals. Implementation of ICT projects. Structured cabling. HFC networks. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210002 | Computing | Semester 1 | - Computer fundamentals. - Algorithms. - Programming. - Introduction to operating systems, databases, and software programs with applications in engineering. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040012 | Communications Systems | Semester 1 | General aspects of a communications system: rate, power, and BER. Wireless channel. Modulations and coding. Basic transmission techniques. Impact on communications systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210144 | Transients in Electrical Machines and Drives | Semester 2 | 1. ELECTROMECHANICAL ENERGY CONVERSION 2. TRANSFORMATIONS OF VARIABLES 3. INDUCTION MACHINES 4. SYNCHRONOUS MACHINES 5. LINEARIZATION AND REDUCED MODELS OF AC MACHINES 6. ELECTRICAL DRIVES 7. CONTROL TECHNIQUES |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210035 | Power Production Systems | Semester 2 | Verification report descriptors: Power plant cycles: steam turbines, gas turbines, combined cycles, and reciprocating internal combustion engines. Specific features of the cycles depending on the heat source used. Content structure 1. Introduction: basic concepts, typology, and current status of power generation systems. 2. Steam power plants. 3. Gas turbines. 4. Combined cycles 5. Reciprocating internal combustion engines. 6. Cogeneration . 7. Advanced power generation systems. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280012 | Computers fundamentals | Semester 1 | CONTENT: Internal workings of computers. Operating systems. Further development of computer programming. THEMATIC BLOCKS: The course content is divided into three main thematic blocks: - Block I: The different forms of information representation in a computer will be studied. The historical background and von Neumann architecture will be studied, presenting the basic elements of a computer at both the structural and functional model level. - Block II: In this block, the computer is studied at the conventional machine and micromachine level. To illustrate the different concepts, both fictitious computers oriented towards teaching and commercial microprocessors will be used. The simulators of these machines will allow the student to present the different concepts acquired in this block in a visual and practical way. The concept of exception and the management of peripherals in a computer will also be studied. - Block III: Introduction to operating systems. Functions of an operating system. Process administration and planning. Virtual memory systems. The course will be complemented with computer practices that offer a first approximation to assembly programming. The student will be able to apply the acquired concepts related to the instruction set and addressing modes by solving a series of proposed problems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560028 | Environmental Technologies | Semester 2 | Characteristics of solid waste, water discharges, and atmospheric emissions and their effects on the environment. Environmental legislation. Pollution prevention. Treatment technologies, fundamentals, and characteristics of pollutant purification processes. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560036 | Consumer electronics | Semester 2 | Laptops, audio and video playback, digital cameras, video game consoles, television and digital audio, mobile phones, PDAs. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560061 | Electronic Technology | Semester 1 | Synchronous and asynchronous digital circuits. Microprocessors. Analog-digital electronic systems. Industrial applications. |
| M143 | Master's Degree in Aeronautical Engineering | 51430057 | Space Vehicle Systems | Semester 1 | Space Environment. Mission Analysis. Launch Systems. Orbit Control System. Power System. Thermal Control System. Communications System. Configuration and Structure System |
| M143 | Master's Degree in Aeronautical Engineering | 51430005 | Airport Operations Supplements | Semester 2 | 0.- INTRODUCTION TO THE COURSE 1.- INTERNATIONAL REGULATIONS AND ORGANIZATIONS 1.1.- Legal problems raised by commercial aviation. 1.2.- Evolution of Aeronautical legislation. 1.3.- Types of Air Transport. 1.4.- International Conventions. 1.5.- Chicago Convention. 1.6.- Warsaw Convention. 1.7.- International Civil Aviation Organization (ICAO). 1.8.- Other organizations similar to ICAO. 1.9.- Air Navigation Organizations. 1.10.- International Air Transport Association (IATA) 2.- CIVIL AVIATION ADMINISTRATION 2.1.- Spanish Civil Aviation Administration Historical evolution DGAC AESA Applicable regulations 2.2.- European Civil Aviation Administration JAA EASA EASA regulatory framework Main actors EASA regulatory process The Base regulation 2.3.- Initial airworthiness: EASA Part 21 Certification Type investigation Subpart J DOA Production POA 2.4.- Maintenance organizations: EASA Part 145 Requirements Means Personnel - Certifiers Entry into service certificate 2.5.- Continued airworthiness Part M Responsibilities in continuing airworthiness TAC operations Tasks in continuing airworthiness Continuing airworthiness organizations CAMO 2.6.- Air Transport Safety. Operational Safety Reason Model Human Factors in Air Transport Safety culture. Safety Management: The SMS Accident Investigation 3.- AIRPORT ORGANIZATION 3.1.- Introduction Aerodromes and Airports. General structure of the Airport System. RD 2591/1998 On Airport Management. The Master Plan The Airport within the General Transportation System. Organizational Forms of Airport Operations: Landside and Airside Different approaches to Airport Operations. Phases of Airport Operation Design. Economic aspects of Airport Operations. 3.2.- Airport Service Organization. Ownership and management modalities. Services under the responsibility of Civil Aviation. "Airside" Services "Landside" Services. Airport Organization. Operations Department. Maintenance Department. Medical Service Coordination Center - Operations Office 3.3.- Basic operational activities Passenger handling Baggage handling Handling 3.4.- Operational restrictions Visibility Braking effectiveness Pavement resistance Wake turbulence Wind shear and microbursts Birds 4.- AIRPORT TERMINALS 4.1.- Typology Generalities. Type classification. Levels. Terminal design methodology 4.2.- Description and sizing of a Terminal. Factors affecting sizing. Terminal flows and activities. Departures. Arrivals. 4.3.- Complementary spaces. 4.4.- Public information systems. 4.5.- Baggage handling in the Terminal Building. 4.6.- General facilities. 4.7.- Car access and parking. 4.8.- Airport buildings. BIBLIOGRAPHY ¿ Airport Services. A. Carmona. AENA Foundation. Airports Systems, Planning, Design and Management. R. de Neufville, A. Odoni. McGraw-Hill Publishing. Air Transport. Arturo Benito. ETSIA Publications of Madrid. Airport Engineering. Marcos García Cruzado. ETSIA Publications of Madrid. Airport Operations. Marcos Garcia Cruzado. AENA Publication Aeronautical Engineering Notebooks. Vicente Cudós Samblanca. Airport Planning. Marcos García Cruzado. ETSIA Publications of Madrid. Aeronautical Law. L. Tapia. Bosch Publishing. |
| 197 | Degree in Aerospace Engineering | 1970056 | Structural integrity of mechanical systems | Semester 2 | Topic 1: Failure in mechanical systems. Types of failure. Description by their occurrence over time and by the type of stress that produces them. Examples. Topic 2: Introduction to fatigue. Definition. Description of the process: crack initiation, propagation. Characteristics. Fatigue design methods and criteria. Topic 3: Fatigue criteria based on stresses. SN curve. Fatigue limit. Factors influencing the SN curve: stress concentration, surface finish, size, type of load, stresses, etc. Generation of residual stresses and their effect. Fatigue design considering these factors. Topic 4: Fatigue criteria based on strains. The local deformation method. Cyclic behavior: se curve. The eN curve. Approximations to the eN curve. Modifications to the curve by mean stress. Neuber's rule. Topic 5: Application of fracture mechanics to the analysis of fatigue crack growth. Introduction. Growth criterion. Crack growth modes. Stress intensity factor. Plastic zone. Cyclic plastic zone. Prediction of fatigue crack growth. da-dN curve: regions of the curve, growth threshold. Crack closure due to plastification and βKef. Influence of R on growth. Growth of small cracks. Effect of overloads. Determination of growth life. Topic 6: Fatigue in notches. Stress and strain concentrators and gradients. SN approach to notched components. Definition of Kf. Critical distance methods. eN approach. Neuber's method. Fracture mechanics in notched components. Topic 7: Fatigue under variable amplitude loading. Cumulative damage; Miner's rule. Cycle counting methods. Life prediction methods under variable loads. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830011 | Waste Engineering | Semester 1 | Domestic waste: collection and management. Characterization and treatment of hazardous waste. Biological treatments. Thermal treatment. Waste landfill. Radioactive waste. Soil reclamation. Topic 1. Introduction. Waste. General problems. Topic 2. Legislation. Characterization of domestic and commercial waste. Management and characterization of hazardous waste. Topic 3. Urban waste management and collection systems. Recycling. Topic 4. Urban waste processing and separation technologies . Topic 5. Biological waste treatment. Composting. Anaerobic digestion. Topic 6. Thermal treatment of waste. Topic 7. Physicochemical treatment of hazardous waste. Topic 8. Stabilization-solidification treatments of hazardous waste. Topic 9. Waste landfill. Topic 10. Radioactive waste management. Topic 11. Consumer goods waste management. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600005 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930050 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 203 | Degree in Industrial Technology Engineering | 2030142 | Obtaining and Recycling Materials | Semester 2 | INTRODUCTION Product life cycle Legislation Economic aspects of raw material extraction and recycling COMMON RAW MATERIAL PREPARATION PROCESSES Size reduction Separation operations Concentration operations Thermal transformation Handling MATERIAL OBTAINING Primary steelmaking. Extraction of copper, aluminium and other non-ferrous metals. Synthesis of resins and plastics. Purification, synthesis and preparation of ceramic raw materials. Cement production Glass production Fiber, wood and paper production RECYCLING OF MATERIALS Waste recovery routes Collection operations, equipment dismantling and material selection Secondary steel industry Recycling of other metals and alloys Recycling of plastics and tires Recycling of glass, light bulbs, etc. Recycling of ceramics in construction Recycling of wood, cardboard and textiles Recycling and sustainability PRACTICES Use of Edupack 3 1.5h Obtaining practices 2 1.5h Recycling practices To be replaced by possible visits |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950018 | Advanced Simulation of Chemical Processes | Semester 2 | The subject is divided into two thematic blocks, each one related to the two types of tools or approaches to process simulation in chemical engineering: Block 1: Steady-state process simulation with commercial simulators Block 2: Analysis and design of process equipment using CFD simulation The first block will explain the functionalities and general characteristics of process simulators and those of the simulator selected for the subject. Aspects such as property calculation, selection and adjustment of thermodynamic methods, process unit models, convergence strategies, analysis tools and energy integration will be addressed. The second block will explain the fundamentals and methodologies for solving engineering problems using CFD techniques. The main objective of this part is to learn how to use a commercial CFD program in user mode, although an introduction to the bases and fundamentals of calculation will be made to understand the numerical methods and resolution schemes used by a commercial CFD simulator. Likewise, emphasis will be placed on understanding the structure of the conservation equations that govern the problems, the specific sub-models to be implemented in each particular case, their dominant parameters and the importance of creating an adequate mesh, applying the appropriate boundary conditions to the computational domains and performing a critical analysis of the solution. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270063 | Consumer electronics | Semester 2 | Laptops, audio and video playback, digital cameras, video game consoles, television and digital audio, mobile phones, PDAs. |
| 208 | Degree in Chemical Engineering | 2080030 | Control and Instrumentation of Chemical Processes | Semester 2 | Dynamic characterization, controllability, PID and advanced control, sensors, final control elements, control system hardware. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040031 | AI Techniques in Distributed Systems | Semester 1 | - Introduction to the subject. - Perfect secrecy and quantum key distribution: Perfect secrecy and Vernan cipher. Quantum cryptography. Quantum key distribution. Shared key distribution. - Data analytics and machine learning on graphs and networks: Construction of graphs and networks from data. Random networks, small-world networks, and scale-free networks. Platforms for graph-based data processing. Types of graphs. Centrality analytics, bottleneck identification, interpretation and implementation of the PageRank algorithm. Network robustness against failures and attacks. Practice. - Automatic community detection: Complexity analysis of the problem. The most popular heuristic solutions. The Laplacian matrix and its interpretation. Graph cut, Kerningan-Lin, ratio cut, normalized cut, and Fiedler's solution algorithms. Data and graph embeddings. Spectral clustering. Agglomerative and divisive hierarchical clustering. The Girvan-Newman algorithm. Modularity and community number detection. Community validation. The Louvain algorithm and its modularity optimization. Ego networks/graphs and an individual's social circles. Consumer clustering and recommendation techniques. Practice. - Data dimensionality reduction: Low-rank approximations, classical and general multidimensional scaling, Sammom mapping, manifolds and nonlinear embeddings: ISOMAP, t-SNE, UMAP. Examples. Practice. - Automatic information retrieval: Feature extraction with pre-trained deep neural networks. Instance retrieval. Nearest neighbor and scalable approximations for massive datasets. Small-world hierarchical navigation networks. Visualization of data and image clusters. Applications. Visualization of features learned by a deep neural network for simple images and databases. - Generative models, signal separation, and Bayesian learning: Component analysis of observations, PCA, SVD, ICA, NMF, signal separation, generative models. Federated learning. Elements of estimation and decision theory. Regression and regularization, classification. Predictive evaluation and model selection. Practical exercises. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280006 | Company | Semester 2 | Adequate understanding of the concept of business, the institutional and legal framework of business, and business organization and management. |
| 225 | Degree in Civil Engineering | 2250009 | Mathematics III | Semester 2 | Calculus in several variables: -Partial derivatives. -Applications of partial differentiation. -Optimization of scalar fields. -Multiple integrals. -Line integrals. -Surface integrals. |
| M143 | Master's Degree in Aeronautical Engineering | 51430022 | Mechanical design of components and aerospace systems | Semester 1 | STRUCTURAL INTEGRITY OF MACHINE ELEMENTS Machine failure Introduction to linear elastic fracture mechanics Growth of large fatigue cracks Fatigue at high cycles Fatigue at low cycles POWER TRANSMISSION SYSTEMS Mechanical transmissions Power transmission shafts Bearings Couplings Belts and chains Gears Fluid transmissions Pumps Cylinders Accumulators Tanks Pipes Circuits and symbols |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270027 | Business creation | Semester 2 | Block 1: General Concepts. Block 2: Creativity . Block 3: The Business Plan. Block 4: Legal Forms. Block 5: Financial Statements. Financing Models. Block 6: Investment Analysis. Block 7: Strategic Management Models. Block 8: Adding Value to the Business Model. Block 9: Draft Business Plan. |
| 208 | Degree in Chemical Engineering | 2080014 | Circuit theory | Semester 1 | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210031 | Thermal Installations | Semester 2 | 1. Fundamentals of air conditioning and DHW. 2. Air treatment. 3. Thermal load . 4. Fluid transport. 5. Thermal generators . 6. Fundamentals of industrial thermal installations. 7. Heat transfer fluids. 8. Steam installations. 9. Refrigeration installations. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900018 | Numerical methods | Semester 1 | Knowledge of advanced aspects of mathematical analysis and its applications to industrial engineering. Differential equations and systems of equations. Partial differential equations. Examples from engineering. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210086 | Organization of Human Resources and Prevention of Occupational Risks | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| 208 | Degree in Chemical Engineering | 2080020 | Fluid mechanics | Semester 2 | LESSON 1. GENERAL CHARACTERISTICS OF FLUIDS. LESSON 2. THERMODYNAMICS OF FLUID-MECHANICAL PROCESSES. LESSON 3. MACROSCOPIC FORCES ON FLUIDS. FLUIDOSTATICS. LESSON 4. FLUID KINEMATICS. LESSON 5. MASS, MOMENTUM, AND ENERGY TRANSPORT PHENOMENA. LESSON 6. GENERAL EQUATIONS OF FLUID MECHANICS. LESSON 7. DIMENSIONAL ANALYSIS AND PHYSICAL SIMILARITY. LESSON 8. UNIDIRECTIONAL MOTION AND QUASI-UNIDIRECTIONAL LAMINAR MOTION OF LIQUIDS. LESSON 9. FLOWS AT LARGE REYNOLDS NUMBERS. LESSON 10. TURBULENT FLOW IN DUCTS. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980032 | Thermosoles central | Semester 2 | 1.- The energy market: needs and requirements 2.- Solar thermal power plants. Introduction to the technology 3.- Phases of a solar thermal power plant project 4.- Design and modeling of solar thermal power plants - Solar field - Thermal energy storage system - Power block - Balance of plant - Economic-financial model 5. Practical cases: feasibility analysis Case a): Parabolic trough collectors Case b): Central receiver system 6.- Operation and maintenance of solar thermal power plants 7.- Improvements and advanced concepts. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210016 | Extension of Mathematics and Numerical Methods | Semester 2 | Thematic Block 1.- Analysis in Complex Variables and Transforms. Thematic Block 2.- Introduction to Numerical Methods. Thematic Block 3.- Extension of ODEs. Numerical Solution. Thematic Block 4.- Extension of PDEs. Numerical Solution. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040032 | Communication Technologies in Biomedicine | Semester 1 | e-Health Point of care Biomedical sensors Body sensor networks Antennas for biomedical sensors Intrabody communications Communication standards for PAN environments Communications in WAN environments Electromagnetic exposure regulations and legislation Interaction of electromagnetic fields with biological tissues Therapeutic applications of electromagnetic fields |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210011 | electronics | Semester 1 | Devices. Polarization. Amplifiers. The Operational Amplifier and its Applications. Logic Families. Introduction to Digital Electronics. Introduction to Communications. |
| 225 | Degree in Civil Engineering | 2250035 | Extension of Structural Calculation | Semester 1 | Finite element method. Structural dynamics. Laminar structures. Plate buckling. Tanks and silos. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210053 | Energy Regulation and Certification | Semester 1 | 1. Thermal load and demand of the premises 2. Demand calculation programs 3. Regulations: CTE-DB-HE1 4. Regulations: CTE-DB-HE2 5. Regulations: CTE-DB-HE3 6. Energy Certification of buildings (CEE) 7. CEE: CALENER-VYP reference programs 8. CEE: CALENER-GT reference programs 9. Existing CEE: CE3 Program 10. Regulations: CTE-DB-HE0 11. Pre-dimensioned for compliance with the RCEE |
| 225 | Degree in Civil Engineering | 2250005 | Physics II | Semester 2 | Fluids, Electromagnetism, Fundamentals of Thermodynamics. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270024 | Occupational and Industrial Safety | Semester 1 | BLOCK I. General introduction and legislative bases BLOCK II. Occupational and industrial safety BLOCK III. Notions of Industrial Hygiene BLOCK IV. Study of practical cases |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270067 | Introduction to Matlab | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270009 | Physics II | Semester 2 | Electromagnetism, Fundamentals of Thermodynamics |
| M143 | Master's Degree in Aeronautical Engineering | 51430058 | Applied orbital mechanics | Semester 2 | Computational Orbital Mechanics. Space Surveillance. Orbit Determination. Orbital Disturbances. |
| 197 | Degree in Aerospace Engineering | 1970037 | Manufacturing Facilities and Production Systems | Semester 2 | BLOCK I: Manufacturing Facilities and Systems I.1 Introduction I.2 Manufacturing Automation I.3 Material Handling, Storage and Identification I.4 Manufacturing Systems I.5 Verification and Control BLOCK II: Production Planning and Management II.1 Plant Layout. Types of Processes II.2 Demand Forecasting II.3 Production Planning II.4 Inventory Management II.5 MRP (Material Requirement Planning) II.6 Lean Manufacturing |
| 199 | Degree in Telecommunications Technology Engineering | 1990085 | Applied Optics | Semester 2 | Optical observation instruments. Photonics. Digital cameras. 2D and 3D visualization systems and techniques. Non-visible imaging systems. Optical technologies for engineering. |
| 199 | Degree in Telecommunications Technology Engineering | 1990050 | Database design | Semester 1 | Normal forms, database design, and server installation and configuration. |
| 199 | Degree in Telecommunications Technology Engineering | 1990051 | Equipment for Multimedia Information Systems | Semester 1 | Electronic equipment and systems for the capture, transport, representation, processing, storage, management and presentation of multimedia information |
| 199 | Degree in Telecommunications Technology Engineering | 1990093 | Distributed Systems and Web Services | Semester 2 | Distributed Object Systems. Web Services: Architecture and Implementation. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900030 | Geotechnical Engineering | Semester 1 | Introduction. Initial stress state in soils and rocks. Boundary conditions. Semi-coupled, undrained, and consolidated analyses. Selection of models and constitutive parameters. Calibration of numerical models. Parametric sensitivity studies. Excavations and retaining structures. Shallow and deep foundations. Stability of slopes and rock masses. F/C reduction finite element model. Problems with consolidation. Extension to Environmental Geotechnics. Models and constitutive parameters. Applications to civil engineering. |
| 203 | Degree in Industrial Technology Engineering | 2030145 | Operations Programming | Semester 1 | Systems for operations programming: models, resolution methods and support tools. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210025 | Thermal Machines | Semester 1 | Block 1: The heat engine - Fluid engine. Motor and generating machines. Hydraulic and thermal machines - Classification of thermal machines according to the type of flow: volumetric and dynamic - Use of thermal machines: applications and operating ranges - Characterization of gas properties: pure substances and mixtures - Introduction to similarity analysis: specific speed and diameter - Fundamentals of compression and expansion: thermodynamic analysis of the process Block 2: Volumetric thermal machines - Introduction to volumetric thermal machines - Characteristic parameters of volumetric machines: capacity, volumetric efficiency, mechanical efficiency, isentropic efficiency - Effect of the working fluid on the characteristics of the volumetric machine - Reciprocating volumetric compressors: piston, diaphragm - Rotary volumetric compressors: fixed/moving vanes, spiral, claw, lobes, screw - Volumetric expansion machines: reciprocating piston, rotary screw - Characteristic curves of volumetric machines - Considerations on the mechanical design of volumetric machines Block 3: Thermal turbomachines - Introduction to isentropic flow in variable section ducts - Fundamental equation of turbomachines. - Blade cascades. Nomenclature of a cascade. - Axial flow turbines. - Axial turbochargers - Centrifugal and mixed flow turbochargers - Radial turbines - Characteristic curves of thermal turbomachines - Considerations on the mechanical design of turbomachines Block 4: Installations - Design and specifications of compression trains - Effect of refrigeration on the compression process - Compressor regulation - Application examples |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040009 | Systems and Services Integration | Semester 1 | Block I: Virtualization Block II: Services and SOA Architecture Block III: Linux Administration and Services |
| 208 | Degree in Chemical Engineering | 2080027 | Energy Technology | Semester 1 | I. General information on energy technology II. Heat transfer technology: Heat exchange equipment III. Thermal energy generation technology IV. Introduction to refrigeration production technology. |
| 208 | Degree in Chemical Engineering | 2080006 | Mathematics II | Semester 1 | Differential and integral calculus in one variable. Differential equations. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210041 | Solar Power Plants | Semester 1 | 1. Introduction to Concentrating Solar Thermal Power Plants 2. Solar Resource 3. Linear Focus Technologies: Parabolic Trough Concentrators and Linear Fresnel Concentrators a. General Description b. Concentrator System c. Thermal Fluid System d. Thermal Energy Storage System e. Power Conversion System f. Balance of Plant g. Design and Analysis of Linear Focus Solar Thermal Power Plants 4. Point Focus Technologies: Central Receiver Systems and Parabolic Dishes a. General Description b. Concentrator System c. Thermal Fluid System d. Thermal Energy Storage System e. Power Conversion System f. Balance of Plant g. Design and Analysis of Linear Focus Solar Thermal Power Plants 5. Other Applications of Concentrating Solar Thermal Power Systems a. Process Heat b. Hybrid Power Plants c. Solar Chemistry 6. New Developments: Advanced Cycles |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560038 | Efficient Management of Electrical Energy | Semester 2 | Energy audits. Electricity rates. Energy efficiency in transformers. Energy efficiency in motors. Energy efficiency in variable speed drives. Economic section of facilities. Instrumentation for energy audits. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560006 | Physics II | Semester 2 | Electricity and Magnetism. Fundamentals of Thermodynamics. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630005 | Advanced Project Management | Semester 1 | BLOCK I: FUNDAMENTALS, TOOLS, AND METHODOLOGIES. BLOCK II: CONTEXT OF PROJECT EXCELLENCE. BLOCK III: AREAS OF KNOWLEDGE. BLOCK IV: PROJECT MANAGER COMPETENCIES. BLOCK V: APPLICATIONS AND CASE STUDIES |
| 208 | Degree in Chemical Engineering | 2080038 | Simulation and Optimization of Chemical Processes | Semester 2 | - Chemical process simulation. - Commercial simulators. - Chemical process optimization and evaluation. |
| 208 | Degree in Chemical Engineering | 2080064 | Applied Optics | Semester 2 | Optical observation instruments. Photonics. Digital cameras. 2D and 3D visualization systems and techniques. Non-visible imaging systems. Optical technologies for engineering. |
| 199 | Degree in Telecommunications Technology Engineering | 1990072 | Bioengineering | Semester 2 | - Basic concepts and applications in bioengineering. - Future development prospects. - Knowledge of the technological areas involved. - Medical applications. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210044 | Energy Efficiency in Industrial Sectors | Semester 1 | I- Simulation of thermal, power, steam, and condensate generation networks. II- Identification and evaluation of energy-saving projects in steam and condensate networks. Marginal mechanisms for economic valuation of energy in complex steam networks. III- Energy management systems in industries according to ISO 50001. IV- Industry 4.0 and industrial energy efficiency. V- Introduction to the simulation of energy systems using machine learning techniques. |
| 225 | Degree in Civil Engineering | 2250073 | Transport and Urban Services Complements (CC, HL) | Semester 1 | BLOCK 1 TRANSPORTATION COMPLEMENTS The urban, interurban and regional transport system. Mobility and flows. Demand analysis. Modality and modal split. Networks and assignment. Modeling and simulation. Demand and flow estimation and forecasting. Costs, benefits, financing and pricing. Externalities. Project and investment evaluation. BLOCK 2 URBAN SERVICES COMPLEMENTS Water supply and distribution. Distribution networks. Water treatment for supply. Collector and sanitation network projects. Urban water purification. Urban water cycle management. Design and management of urban waste collection systems. Calculation. Design and operation of facilities for urban waste management. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210118 | Efficient Design in Water Desalination Facilities | Semester 2 | BLOCK I: BASIC CONCEPTS OF DESIGN, OPERATION AND MODELING OF REVERSE OSMOSIS (RO) DESALINATION SYSTEMS (4 weeks) Chapter 1. INTRODUCTION TO WATER DESALINATION. Chapter 2. INTRODUCTION TO MODELING OF REVERSE OSMOSIS DESALINATION SYSTEMS. Chapter 3. MODELING OF RO DESALINATION SYSTEMS. Chapter 4. INTRODUCTION TO THE DESIGN OF WATER DESALINATION FACILITIES. BLOCK II: MODERNIZATION OF EXISTING RO PLANTS (1 week) Chapter 5. DESIGN PROBLEMS APPLIED TO MODERNIZATION OF RO PLANTS. BLOCK III: PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY (3 weeks) Chapter 6. BASIC CONCEPTS ON THE DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 7. PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 8. COUPLING OF PHOTOVOLTAIC SYSTEMS TO PUMPING SYSTEMS. BLOCK IV: PRE-DESIGN OF WATER DESALINATION INSTALLATIONS IN INDUSTRIAL APPLICATIONS (2 weeks) Chapter 9. PRE-DESIGN OF DESALINATION INSTALLATIONS FOR HYDROGEN PRODUCTION. Chapter 10. PRE-DESIGN OF DESALINATION INSTALLATIONS INTEGRATED IN POWER PRODUCTION PLANTS. BLOCK VI: INTRODUCTION TO RESEARCH (1 week) Chapter 11. RESEARCH IN REVERSE OSMOSIS PLANTS; PROCESSES IN DEVELOPMENT. BLOCK VII: PRACTICAL DESIGN CASES (2 weeks) Chapter 12. PRACTICAL DESIGN CASES IN VARIOUS GEOGRAPHICAL LOCATIONS Chapter 13. PRACTICAL DESIGN CASES FOR VARIOUS APPLICATIONS. |
| 225 | Degree in Civil Engineering | 2250008 | Mathematics II | Semester 1 | Calculus in one variable - Derivatives - Curve representation - Integration - Geometric applications of integration - First-order differential equations |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280051 | Perception Systems | Semester 1 | CONTENT: Perception systems. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280029 | Robotics Fundamentals | Semester 2 | CONTENT: Robot morphology. Robot modeling. Components of robotic systems. Basic robot programming. Robotics applications. THEMATIC BLOCKS: # Block 1. Introduction to Robotics # Block 2. Robot Modeling # Block 3. Robot Control # Block 4. Robot Programming and Implementation |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560004 | Graphic expression | TO | 1. Geometry of Space. Theory of Representation. 2. The Dihedral System Using the Direct Method as a Tool for Industrial Drawing. Procedures. 3. Surfaces. 4. Technical Application Surfaces. 5. Ducts, Elbows, Transition Surfaces. Hoppers. 6. Introduction to the Dimensioned Drawing System. Applications in Industrial Engineering. 7. Standardization of Technical Drawings. 8. Views. 9. Dimensioning. 10. Tolerances. Standardization. 11. Representation of Elements and Systems of Removable and Fixed Connections. 12. Functional Dimensioning. 13. Indication of Surface States. Geometric Tolerances. 14. CAD Tools for Design (3D) and Engineering Drawing (2D). The previous blocks materialize the contents of the subject included in the Verification Report: "Spatial vision. Graphic representation techniques. European and American representation systems. Metric and descriptive geometry. Standardization of graphic documentation for an engineering project. Computer-aided drawing." |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560027 | Chemical technology | Semester 1 | BLOCK 1: The chemical industry and chemical engineering. BLOCK 2: Basic concepts in chemical engineering. Equipment and processes. BLOCK 3: Material and energy balances. BLOCK 4: Tools for solving material and energy balances. Process simulators. BLOCK 5: Operations and processes. Application of balances, kinetics, and chemical equilibrium to reactor design. |
| M143 | Master's Degree in Aeronautical Engineering | 51430013 | Space Vehicle Dynamics | Semester 1 | Kinematics and dynamics of a spacecraft's attitude. Spacecraft attitude control and estimation. Advanced orbital mechanics. Orbit optimization, control, and estimation techniques. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600010 | Automation Projects | Semester 1 | Automation project - Project phases - Approach, equipment selection - Documentation, Technical Reports: Implementation of the automation project - Programming structure - Programming - Simulators - Communications and HMI |
| 197 | Degree in Aerospace Engineering | 1970070 | Aerospace Materials | Semester 2 | THEORY I. INTRODUCTION II. LIGHT ALLOYS III. OTHER METALLIC MATERIALS IV. POLYMERIC MATERIALS V. CERAMICS VI. COMPOSITE MATERIALS VII. ADVANCED MATERIALS AND TECHNOLOGIES VIII. NON-DESTRUCTIVE TESTING IX. PRACTICE PROBLEMS: 1 (aluminium) 2 (titanium) 3 (steels) 4 (PMC and MMC) 5 Technical Visit The developed program as well as the tempering, both theoretical and practical, will be included in the Virtual Teaching of the subject |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600001 | Smart Building Automation | Semester 1 | The course is divided into three thematic sections: Thematic Section I (Building Installations, Current Regulations, and Home Automation Projects): This section describes the existing installations in buildings and presents the current regulations in Spain related to their automation. The course covers the implementation of the home automation project, construction management, completion certification, and maintenance. Thematic Section II (Building Automation Technologies): This section focuses on presenting the main home automation technologies and microgrid systems used, with particular emphasis on those that are typically used for the automation of large buildings, as well as the associated control problems. |
| 197 | Degree in Aerospace Engineering | 1970051 | Air transport exploitation | Semester 1 | Technical and commercial exploitation. Transportation demand Service planning, design, and optimization |
| M164 | Master's Degree in Electrical Energy Systems | 51640012 | Active Distribution Networks and Demand Management | Semester 1 | Block I Generalities and Characteristics of Distribution Networks Lesson 1: Introduction and generalities Lesson 2: Components and characteristics of distribution networks Lesson 3: Microgrids Block II Modeling and Analysis of Distribution Networks Lesson 4: Electrical modeling of lines and loads Lesson 5: Electrical modeling of transformers Lesson 6: Load flows in distribution networks Block III Optimization of Medium Voltage Networks Lesson 7: Characteristics of improvement in the operation of MV networks Lesson 8: Voltage and reactive control in Medium Voltage networks Lesson 9: Network reconfiguration Block IV Optimization of Low Voltage Networks Lesson 10: Characteristics of improvement in the operation of LV networks Lesson 11: Control in Low Voltage networks Block V Demand Management Lesson 12: Demand Management |
| M165 | Master's Degree in Thermal Energy Systems | 51650008 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M165 | Master's Degree in Thermal Energy Systems | 51650010 | Energy Management in Industry | Semester 2 | 1. Energy consumption in the industrial sector. 2. Energy audit methodology. 3. Thermal installations in industry. 4. Industrial equipment and processes. 5. Energy-saving measures. 6. Regulations |
| M165 | Master's Degree in Thermal Energy Systems | 51650001 | Thermosoles central | Semester 2 | 1.- The energy market: needs and requirements 2.- Solar thermal power plants. Introduction to the technology 3.- Phases of a solar thermal power plant project 4.- Design and modeling of solar thermal power plants - Solar field - Thermal energy storage system - Power block - Balance of plant - Economic-financial model 5. Practical cases: feasibility analysis Case a): Parabolic trough collectors Case b): Central receiver system 6.- Operation and maintenance of solar thermal power plants 7.- Improvements and advanced concepts. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900004 | Civil Construction Accessories | Semester 1 | - Prestressed concrete technology. - HP regulations and calculation bases. - Strength verification criteria, fitness for service, and durability. - Execution control of HP structures. - Construction and maintenance of: road and airport pavements and road surfaces, railway infrastructure; storage facilities and above-ground and underground pipelines. - Structural dynamics. - Shell structures. - Plate buckling. - Composite structure technology. - Regulations and calculation bases for composite structures. - Strength and instability limit states of composite beams and supports. - Connectors. - Fitness for service. - Control, protection, and maintenance of steel and composite structures. - Recommendations for design and maintenance. - Evaluation of public works projects. - Tendering and contracting of public works. - Legal framework. - Task and time scheduling. - PERT and CPM. - Project control. - Cost control. - Human resources. |
| 199 | Degree in Telecommunications Technology Engineering | 1990064 | Electronic Systems for Signal Processing | Semester 1 | Microprocessor Systems Design. Digital Signal Processor. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900009 | Fatigue Design in Civil Engineering | Semester 1 | 1. Physics of fatigue failure. 2. Stress-based fatigue study. 3. Strain-based fatigue study. 4. Crack growth-based fatigue study (fracture mechanics). |
| 199 | Degree in Telecommunications Technology Engineering | 1990037 | Telecommunications Network Management | Semester 2 | Network management models and protocols |
| 199 | Degree in Telecommunications Technology Engineering | 1990038 | Acoustic Engineering | Semester 2 | Sound perception. Octave filters. Isophonic curves. A-weighting law. Radiation from acoustic sources. Point and line sources. Loudspeakers. Flat surfaces. Radiation directivity and impedance. Room acoustics. Diffuse sound field. Reverberation. Absorption. Sound reinforcement and public address systems. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920033 | Biomechanics | Semester 1 | Block 1. Introduction Block 2. Kinematics and kinetics of the musculoskeletal system Block 3. Tissue behavior models |
| 199 | Degree in Telecommunications Technology Engineering | 1990084 | Microsystems | Semester 2 | Devices and models. Design and manufacturing. Applications . |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950007 | Environmental Management in Industry | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210066 | Sustainable Design of Processes and Products (DIS) | Semester 1 | Re-evaluation of process and product design under sustainability criteria |
| 208 | Degree in Chemical Engineering | 2080063 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| M228 | Master's Degree in Operation of Space Systems | 52280013 | Spacecraft Guidance and Navigation | Semester 2 | - Guidance, Navigation, and Control (GNC) of spacecraft. - Attitude Determination and Control Systems (ADCS). - Optimal trajectories. - Attitude and orbit estimation. - Kalman filtering. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980034 | Diagnosis, Testing and Certification of Power Production Systems | Semester 1 | BLOCK I: ENERGY FRAMEWORK OF POWER PLANTS POWER PLANT ELEMENTS POWER PLANT PERFORMANCE ASSESSMENT: REFERENCE CHANGE AND DEGRADATION APPLICABLE REGULATIONS BLOCK II: GAS TURBINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES GAS TURBINES: FAILURE TYPOLOGY STEAM TURBINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES STEAM TURBINES: FAILURE TYPOLOGY ALTERNATIVE ENGINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES ALTERNATIVE ENGINES: FAILURE TYPOLOGY BLOCK III: TOOLS FOR THE IDENTIFICATION/QUANTIFICATION OF DEGRADATION IN WORK CYCLES |
| 199 | Degree in Telecommunications Technology Engineering | 1990077 | Home automation | Semester 2 | The course content will be divided into three main thematic blocks: - Block I: Introduction to the basic concept of home automation networks in buildings. The basic characteristics of home automation systems will be explained and detailed, including their fundamental elements and the relationships between them. The structure and organization of basic installations in smart homes and buildings in general will be detailed. - Block II: Description of the main home automation technologies available on the market, along with the protocols used. - Block III: Introduction to service robotics and the concept of smart cities. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930051 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| 199 | Degree in Telecommunications Technology Engineering | 1990044 | Electronic Communications Systems | Semester 2 | Equipment and systems for interfacing, data capture and storage, and for terminals intended for telecommunication services and systems. |
| 203 | Degree in Industrial Technology Engineering | 2030168 | Drives and Electric Mobility (EL) | Semester 1 | The contents included in the Verification Report of the Title are the following: Analysis, design, testing, selection and applications of electrical machines Control of electrical machines, variable speed drives and applications Electric vehicles: Motor equipment, torque-speed relationship, traction and braking, energy accumulators, efficiency and energy management The contents of the subject are organized in the following thematic blocks: 1. Introduction to electrical machines and drives 2. Energy and economic efficiency of electrical drives 3. Variation of the speed of asynchronous or induction motors 4. Introduction to vector or oriented field control 5. Application of drives in electric mobility 6. Storage and mechanical system in electric mobility 7. Integration of electrical drives and mechanical systems |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270058 | Industrial Automation and Robotics | Semester 2 | CONTENTS: Introduction to automation. Fundamentals of robotics. Basic robot programming. THEMATIC BLOCKS: Block 1: Industrial Automation. Block 2: Fundamentals of Robotics. Block 3: Basic robot programming. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280027 | Network Architecture | Semester 2 | Descriptors: Taxonomy of telecommunication networks. Telecommunication network architecture. Layer and plane models. Link, network, and transport layers. Thematic blocks: Block 1: Introduction to computer networks and the Internet. Block 2: Introduction to the Application Layer Block 3: The Transport Layer. Block 4: The Network Layer. Block 5: Introduction to the Link Layer. Block 6: The Physical Layer. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280007 | Statistics and Operations Research | Semester 2 | Statistics and optimization. |
| M143 | Master's Degree in Aeronautical Engineering | 51430054 | Manufacturing Technology Complements | Semester 2 | I. INTRODUCTION TO MANUFACTURING II. MEASUREMENT, VERIFICATION AND QUALITY CONTROL TECHNIQUES III. METAL CASTING PROCESSES IV. PLASTIC METAL FORMING PROCESSES V. MACHINING PROCESSES VI. FORMING OF POLYMERIC AND COMPOSITE MATERIALS VII. JOINT FORMING PROCESSES VIII. MANUFACTURING SYSTEMS |
| 197 | Degree in Aerospace Engineering | 1970049 | Airport Construction II | Semester 1 | Fundamentals of airport and infrastructure design and construction. Location, siting, and environmental impact of airports. Field operations. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970040 | Operation and Control of Electrical Systems | Semester 1 | A. Control center architecture B. State estimation in electrical networks C. Frequency and voltage control D. Short and long-term operation planning E. Maintenance of electrical installations F. Project management of electrical installations |
| 199 | Degree in Telecommunications Technology Engineering | 1990028 | Digital signals treatment | Semester 2 | Time and frequency analysis of discrete signals and systems. DTFT, DFT, FFT. Digital filter design. Multi-rate systems. Applications |
| 203 | Degree in Industrial Technology Engineering | 2030062 | Chemical Reactors | Semester 2 | Operations controlled by reaction kinetics and rate, thermodynamics and chemical reaction. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040010 | Advanced Signal Processing in Communications | Semester 2 | Block I: Principles of optimization and advanced signal processing. Block II: Information theory Block III: Information transmission. |
| 225 | Degree in Civil Engineering | 2250048 | Geotechnical Works | Semester 1 | Walls, screens, foundations, piles: design, construction, and calculation. Ground reinforcement methods. Tunnels. Construction in expansive and collapsible soils. Seismic geotechnical engineering. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270014 | Materials and Machine Technology | Semester 1 | Block 1: Introduction Block 2: Fundamentals of materials science Block 3: Materials Properties Block 4: Materials Behavior Block 5: Property Measurement (Tests) Block 6: Introduction to machine technology Block 7: Fundamentals of kinematic and dynamic analysis of machines Block 8: Fundamental concepts: stress and deformation analysis Block 9: Machine elements and installations |
| M143 | Master's Degree in Aeronautical Engineering | 51430049 | Structure Complements | Semester 1 | Prior knowledge and skills: The following knowledge is considered essential for following the subject: Calculus Algebra Rational Mechanics Strength of Materials Thematic blocks Calculation of stresses in bars Introduction to structural analysis Plane lattice systems of articulated structures. General structural calculation methods. Introduction to FEM. |
| M143 | Master's Degree in Aeronautical Engineering | 51430006 | Air Transport Complements | Semester 1 | TOPIC 1: DEMAND MODELS Concept of elasticity. Elasticity in air transport. Types of models and variables. Constant elasticity models. Non-constant elasticity models. Fitting the constant elasticity model. Interpretation of the fit. Collinearity of explanatory variables. Gravity models. Practical cases of demand models. Dynamic pricing. TOPIC 2: CHOICE MODELS Choice of transport mode. The logit model. Concept of utility. Types of variables on which utility depends. Fundamentals of RUM theory. Practical case of a modal choice model. Model fit. Interpretation of results. Estimating the cost of time for the user. Types of surveys. TOPIC 3: DETERMINISTIC QUEUING ANALYSIS Definition of a queuing system. Counting process. Poisson process. Properties of the Poisson distribution. The aircraft and passenger arrival process. Cumulative curves. Types of queuing analysis. Queue formation. Little's formula. Queue reduction. Group service. Airport capacity. Simulation of a Poisson process. Simulation of a queue with one server. Simulation of a queue with several servers. Analytical model for constant service time: application to landings/takeoffs. TOPIC 4: QUEUING THEORY Standard notation. The M/M/1 queue. The M/M/c queue: several servers. The M/M/infinity queue: unlimited service. The M/G/1 queue: Pollaczek-Khintchine formula. The M/M/c/c queue: Erlang formula. Approximations for G/G/1 and G/G/c queues. TOPIC 5: APPLICATIONS OF LINEAR PROGRAMMING IN AIR TRANSPORT Fundamentals of linear programming and main results. Fleet assignment. Aircraft rotation. Crew assignment. Work shift scheduling. Design of a passenger transport network. Assignment of boarding gates: the assignment problem. Freight transportation network: the transportation problem. Analysis of airport efficiency. BIBLIOGRAPHY: ¿Airline operations and Scheduling¿ M. Bazargan (2005). Ashgate. ¿Operations Research in Space and Air¿ TA Ciriani, G. Fasano, S. Gliozzi, and R. Tadei (2003) Kluwer. Queuing Methods for Services and Manufacturing (1997) RW Hall. Prentice Hall. Fundamentals of Queuing Theory D. Gross, C. Harris. (1998) Wiley. ¿An Introduction to Queuing Theory: Modeling and Analysis in Applications¿ (2008) UN Bhat. |
| M146 | Master's Degree in Industrial Engineering | 51460064 | Advanced Fracture Mechanics and Fatigue | Semester 2 | BLOCK 1: Advanced Fracture Mechanics . Elasto-Plastic Fracture. Fracture in Quasi-Brittle Materials. BLOCK 2: Fatigue I. Fatigue behavior and growth modeling of small cracks. Fatigue under stress gradients in the small-crack regime. BLOCK 3: Fatigue II . Multiaxial Fatigue. Fretting Fatigue. Fatigue under Random Loading. |
| 197 | Degree in Aerospace Engineering | 1970055 | Systems Integration and Functional Testing | Semester 2 | - Aircraft Systems Integration. - Functional Testing Design and Implementation. |
| 197 | Degree in Aerospace Engineering | 1970014 | Elasticity and Resistance of Materials | Semester 1 | TOPIC 1. STRESSES. Introduction. Domain and boundary forces. The concept of stress. Cauchy's lemma. Internal equilibrium. Coordinate transformation. Principal stresses. Properties. Invariants. Extreme values of the intrinsic components of the stress vector. Octahedral stresses. Spherical and deviator tensors. Lamé ellipsoid. Mohr's circles. Representation in principal stress space. TOPIC 2. DEFORMATIONS. Introduction. Study of deformation. Green's and Almansi tensors. Small strain tensor. Geometric interpretation of its components. Compatibility equations. Stress-strain correlation. TOPIC 3. LAW OF BEHAVIOR. Introduction. Tensile testing. Generalized Hooke's law for isotropic materials. Alternative forms of Hooke's law for isotropic materials. Value of elastic constants. TOPIC 4. BOUNDARY CONDITIONS. Introduction. Direct boundary conditions. Special boundary conditions. Conditions derived from symmetry. Contact conditions. UNIT 5. THE ELASTIC PROBLEM. Introduction. General formulation of the elastic problem. Displacement formulation: Navier equations. Stress formulation: Beltrami-Michell equations. UNIT 6. THEOREMS AND PRINCIPLES OF ELASTICITY. Introduction. Theorem of virtual work. Theorem of virtual displacements. Theorem of virtual forces. Value of the Strain Energy. Clapeyron's theorem. Superposition principle. Uniqueness of the elastic problem. Saint-Venant's principle. UNIT 7. PLANE ELASTICITY. Introduction. Plane deformation. Generalized plane stress. The plane problem. Airy function. The plane problem in polar coordinates. Planar representation of stresses in the vicinity of a point. Families of curves representative of the plane stress state. UNIT 8. INTRODUCTION TO THE BAR MODEL. Definition of a bar. Saint-Venant's Principle. Solving bar problems with the Theory of Elasticity. Conceptual diagram of the bar model. TOPIC 9. EQUILIBRIUM. External loads. Internal stresses. Differential equilibrium equations. Integration of equilibrium equations. Stress diagrams. Equilibrium equations for the bar. TOPIC 10. COMPATIBILITY. Kinematic assumptions for the bar model. Section movements. 1D deformations. Compatibility equations for the slice. Slender bar model. Compatibility equations for a bar. Support conditions. TOPIC 11. STRESS BEHAVIOR AND CALCULATION. Relationships between 1D stresses and deformations. Dynamic assumptions for the bar model. Stress calculation in the section. TOPIC 12. ISOLATED BAR PROBLEMS. Compilation of equations. Validity of the bar model. Examples. Isotatic and hyperstatic cases. TOPIC 13. BUCKLING OF AN ISOLATED BAR. Previous concepts. Euler's column. Euler's hyperbola. Buckling of elements with imperfections. General equation of the beam-column. Practical calculation method. TOPIC 14. BAR STRUCTURES. Previous concepts. Reference systems. Equilibrium and compatibility equations at a node. Nodes with freedoms. |
| 199 | Degree in Telecommunications Technology Engineering | 1990045 | Digital Electronic Systems | Semester 2 | Digital electronic design based on microprocessor and microcontroller systems. Programmable logic devices. |
| M164 | Master's Degree in Electrical Energy Systems | 51640005 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M190 | Master's Degree in Civil Engineering (2019) | 51900019 | Modeling in Civil Engineering | Semester 2 | PART I Block 1: Concrete structures and bridges. 1.1- Generalities. 1.2- Porticos and arches. 1.3- Plates, diaphragms and walls. 1.4- Bridge slabs and decks. 1.5- Piers and abutments. Block 2: Steel structures and bridges. 2.1- Postcritical models of box girders. 2.2- Diaphragms of metal bridges. PART II Block 3: Wave modeling in intermediate and shallow waters. 3.1- Equation for gentle bathymetric changes. 3.2- Resolution using the Finite Element Method. 3.3- Implementation of the method in one dimension. |
| 199 | Degree in Telecommunications Technology Engineering | 1990060 | Sound and Image Projects | Semester 1 | Methodology, formulation, and development of projects related to sound imaging systems: venues, installations, headends, isolation, production centers, etc. |
| 208 | Degree in Chemical Engineering | 2080005 | Mathematics I | Semester 1 | 1- Conics and Quadrics. 2- Complex Numbers. 3- Matrix Algebra. Systems of Linear Equations. 4- The Vector Space Rn. 5- Orthogonality. Best Approximation. 6- Eigenvalues and Eigenvectors. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940034 | Distribution Systems Control | Semester 2 | BLOCK I Modeling and Machine Learning. I.1 Modeling and Simulation of Distribution Systems: I.2 Machine Learning Techniques: I.3 Estimation. Kalman Filter. I.4. Data Reconciliation and Fault Detection. BLOCK II Planning and Control of Distribution Systems II.1 Economic Planning. II.2. Constrained Control. BLOCK III. Numerical Optimization Techniques. III.1 Quadratic Problems. III.2 Gradential Optimal Methods. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990017 | Biorefineries | Semester 1 | The course is divided into four main sections that cover the following topics: - Fundamentals of Biorefineries: concepts, types, and platforms - Fundamentals of biomass transformation processes - Production of biofuels, biofuels, and bioproducts - Energy, economic, and environmental analysis of biorefineries. The first section develops the fundamental concepts of biorefineries, their classification and typology, the main processes that comprise them, experiences to date in Spain and around the world, etc. Likewise, the biomass resource, logistics, and the biomass market are studied. The second section studies biomass transformation processes, including physical and chemical pretreatment processes as well as thermochemical, biochemical, and hydrothermal conversion processes. The third section describes the production processes of biofuels (biofuels and chemicals) and bioproducts. Finally, the fourth section presents a detailed analysis of the different types of biorefineries, grouped into two large "families." thermochemical and biochemical, the different platforms that define the various biorefineries currently under development (lipids, sugars, biogas, proteins, synthesis gas, etc.) as well as an analysis of the energy and environmental efficiency of biorefineries. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210021 | Heat Transmission | Semester 2 | BLOCK I. INTRODUCTION TOPIC 1. INTRODUCTION BLOCK II. CONDUCTION TOPIC 2. FUNDAMENTALS OF HEAT TRANSFER BY CONDUCTION TOPIC 3. ONE-DIMENSIONAL CONDUCTION IN A STEADY REGIME TOPIC 4. HEAT TRANSFER ON EXTENDED SURFACES TOPIC 5. CONDUCTION IN A TRANSIENT REGIME BLOCK III. RADIATION TOPIC 6. FUNDAMENTALS OF HEAT TRANSFER BY RADIATION TOPIC 7. RADIANT EXCHANGE BETWEEN TWO SURFACES TOPIC 8. RADIANT EXCHANGE IN ENCLOSURES BLOCK IV. CONVECTION TOPIC 9. FUNDAMENTALS OF HEAT BY CONVECTION TOPIC 10. FORCED CONVECTION TOPIC 11. NATURAL CONVECTION TOPIC 12. CONVECTION WITH PHASE CHANGE |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270022 | Markets | Semester 1 | Market analysis. Marketing. Product policy. Pricing policy. Distribution policy. Communication policy. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210058 | Automobiles (IMF) | Semester 1 | 1. Vehicle dynamics The dynamic behavior of vehicles is analyzed on three levels: Lateral (maneuverability and stability in curves) Vertical (suspension and ride comfort) Longitudinal (acceleration, braking and traction) 2. Main components of the vehicle The elements that affect dynamic behavior are studied: Tires Steering Suspensions Transmission Braking Stability 3. Emerging technologies Basic concepts are introduced on: Hybrid vehicles Electric vehicles 4. Structures and aerodynamics Fundamental aspects related to: The structural resistance of the vehicle The influence of design on aerodynamic behavior 5. Complementary activities Technological visits to companies in the sector Technical talks given by industry professionals |
| 199 | Degree in Telecommunications Technology Engineering | 1990056 | Network Planning and Simulation | Semester 1 | The simulation method. Modeling. Event- and process-driven simulation. Outcome analysis. Confidence intervals. Elements of network models. Simulators. |
| 197 | Degree in Aerospace Engineering | 1970060 | Aircraft Systems | Semester 1 | Aircraft Systems. Physical Fundamentals. General Characteristics. Architecture. Regulations. Design. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990012 | Operation and Control of Chemical Plants | Semester 2 | Chemical Plant Operations Plant-wide Control |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270015 | Electrical technology | Semester 1 | Linear programming. Networks and graphs. Application to modeling and problem solving in organizational engineering. |
| 208 | Degree in Chemical Engineering | 2080039 | Treatment of Gaseous Effluents | Semester 1 | Air pollutant abatement techniques. Industrial design and implementation. |
| 197 | Degree in Aerospace Engineering | 1970062 | Electrical Systems in Aircraft and Airports | Semester 1 | DESCRIPTORS: Power plant. Airport electrical installations. Secondary sources. Aircraft assistance facilities. Electric generators and motors. Aircraft electrical systems. According to these descriptors, the subject content is grouped into the following blocks: Block I. Fundamentals. Block II. Electrical machines. Block III. Aircraft electrical systems. Block IV. Airport electrical installations. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320014 | Aircraft path optimization | Semester 2 | Trajectory optimization techniques. Vertical profile optimization. Horizontal profile optimization. Complete trajectory optimization. |
| 208 | Degree in Chemical Engineering | 2080025 | Experimentation in Chemical Engineering | Semester 2 | 1. Centrifugal fan 2. Fluidized beds 3. Heat transfer 4. Fixed beds 5. Packed tower 6. Hydraulic bench 7. Operations with solids 8. Plate column 9. Filtration of liquid suspensions 10. Pressure drops in pipes and accessories 11. Sedimentation |
| 225 | Degree in Civil Engineering | 2250022 | Urban Planning and Territorial Planning | Semester 2 | Course Content. GENERAL INFORMATION. The content will be taught in two approaches that will coexist throughout the coursework. Both are complementary in their approach to the knowledge they provide. Thus, each topic will present two converging lines of work: Those labeled "theoretical basis" refer to topics necessary for a basic understanding of the discipline, without which it is impossible to address, integrate, and contextualize the practical aspects. Their purpose is to provide tools for understanding the city and its territory by projecting its planning onto its most important constituent factors (physical environment, urban morphology, activities, mobility, etc.) in the current context. Those labeled "applied knowledge" address the description of the urban planner's work through detailed planning, the scale of which is closest to the constructive materialization that urbanization represents. BLOCK 1. THE URBAN AND ITS PLANNING RESOURCES IN THE CURRENT CONTEXT. Topic 1. Theoretical Basis: The urban environment and its current dynamics as an area of challenge for urban and territorial planning and engineering. Applied knowledge: Tools for analyzing urban and territorial space for intervention. Topic 2. Theoretical Basis: Urban Planning and Territorial Planning: historical context and definition of both disciplines. Applied knowledge: Territorial plans as a framework for urban planning and sectoral planning. Topic 3. Theoretical Basis: Urban Planning and Territorial Planning legislation: regulation of comprehensive planning. Applied knowledge: Land classification, urban structure and zoning, planning and management units. Topic 4. Theoretical Basis: Levels of action in the city through urban planning: the planning hierarchy. Applied knowledge: General and detailed planning: scales and levels of definition. BLOCK 2: BASIC FEATURES OF URBAN DEVELOPMENT PLANNING. Topic 5. Theoretical Basis: The redesign of existing cities and the creation of new cities as aspects of urban planning. Applied Knowledge: Definition of an area of intervention: nature of the intervention, legal framework, insertion into the urban structure, determination of pre-existing conditions, and historical research as a means of framing the intervention within the environment. Topic 6. Theoretical Basis: The legal dimension of urban action; modification of land ownership. Information. Applied Knowledge: Public and private sectors and their characterization and implementation in urban planning. Topic 7. Theoretical Basis: The social infrastructure of the city: facilities in the context of planning. Applied Knowledge: Criteria for determining the surface area and characteristics of facility reserves. Topic 8. Theoretical Basis: The definition of open space as a basic element of the city project. Applied Knowledge: Location, design criteria, and integration of open space into urban planning. Topic 9. Theoretical Basis: The requirements of mobility in the configuration of urban space. Applied knowledge: Conditions for the definition and design of the road network. Topic 10. Theoretical basis: The diversity of the urban fabric and its treatment in planning. Applied knowledge: The delimitation of urban planning zones. Topic 11. Theoretical basis: The landscape as a resource in urban planning. Applied knowledge: Visual integration of urban interventions in the city and territory. Topic 12. Theoretical basis: Sustainable urban planning as an integrating framework for actions on the city. Applied knowledge: Integration of sustainability variables into urban design. |
| 225 | Degree in Civil Engineering | 2250028 | Maritime works | Semester 1 | Typology of maritime works Exterior works Shelter works Access works Interior works Docking works |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210008 | Digitalization in Industry (EIDTE) | Semester 2 | - Microcontrollers - FPGAs - PLCs - Embedded systems - Real-time systems |
| 225 | Degree in Civil Engineering | 2250047 | Port Engineering and Operation | Semester 1 | AT000.- INTRODUCTION TO THE COURSE AT000.- Course Presentation AT010 - Ports Approach to the concept of Port. Conceptual model. Morphology of ports. The Dock AT100.- GLOBAL LOGISTICS AT110 - International Trade Trade and the global economy. Drivers of globalization. Levels of economic integration. Patterns of current global trade. GATT Rounds. Export-oriented economy AT120 - Value chains Contemporary production systems. Value chains. Transport of goods and value chains AT130 - Logistics and Distribution Concept of Logistics. Distribution systems. Structure of the distribution of goods. Logistics and transport AT200.- THE MARITIME TRANSPORT SYSTEM AT210.- Maritime Transport Modes of transport. The Ship. The fleet. Economic aspects of maritime transport. Maritime traffic. Maritime transport routes and services AT220.- Integrated transport system . Purpose of intermodality. The container. Containerization of cargo. Freight transport terminals. Intermodal terminals. Costs associated with transport terminals. Relative location. Hinterland and Foreland AT300.- PORT WORKS AND FACILITIES AT310 - Port configuration . Port typologies. Conceptual diagram of a port. Maritime operations. Terminal operations and activities. Berthing and mooring works. Locks. Dredging APL320 - Planning and design of water areas . Vessel maneuverability and hydrodynamic behavior. Maritime access channels. Port maneuvering area. Port basins and berthing areas. Morphological aspects of designs. AT400.- PORT OPERATIONS AND SERVICES AT420.- Port operations and services . Conceptual diagram. Port operators. Sequences of activities in the port area. AT500 - LEGAL AND ECONOMIC STRUCTURE AT520 - Spanish port system . Port regulation in Spain. Organization of services in the ports of Spain. General services. Port services. Maritime signaling service AT530 - Port policy in the European Union . Ports in the European Union. Models of public participation in the port sector. Comparative legislation and administrative organization. Ownership of ports. Functions of the public and private sectors AT600 - PORT TERMINALS AT610 - Port terminal concepts . The port and its terminals. The port terminal as an integrated system AT620 - Liquid bulk terminals . Liquid bulk cargo. Liquid bulk transport vessels. Processes and operating models of the TPGL. Nautical configuration. Machinery and facilities. Liquid bulk terminal configurations AT630 - Solid bulk terminals . Solid bulk cargo. Solid bulk transport vessels. Processes and operating models of the TPGS. Nautical configuration. Machinery and facilities. Bulk terminal configurations. AT641 - Container terminals . Container cargo. Container transport vessels. Operating processes and models. Nautical configuration. Container terminal operations system. Container terminal configurations. AT642 - Container terminals. Design. Preliminary considerations. Design strategy and process. Compendium of handling equipment. Functional design calculation. Application examples. AT650 - Roll-on/Roll-off terminals . RoRo cargo. RoRo transport vessels. Nautical subsystem. Loading and unloading subsystem. Storage subsystem. RoRo terminal configurations. AT700 - RAIL TRANSPORT AND LOGISTICS IN PORTS AT710 - Rail transport in ports . The railway context in Spain. Maritime-rail intermodality in Spain. Railway organization in ports. Railway strategy in ports. Terminal design. Relevant cases of interest. AT720 - Logistics activities in ports. The new economic reality. Logistics and the transport chain. The port and the logistics chain. Logistics activity area. Relevant cases of interest. AT800.- PORT PLANNING AND ORGANIZATION AT810 ¿ Port planning and organization Port planning. Strategic Framework. Strategic Plan. Master Plan. Business Plan. Investment Plan. Port-City Interrelation. AT820 ¿ Port agents and competitiveness The Port Authority. Service companies in the port context AT900.- INNOVATION MANAGEMENT AT910 ¿ Innovation and Information and Communications Technology in ports Application of R&D&I and ICT concepts to port activity. Development areas and management models. Review of the ICT tools commonly used in port areas. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210007 | Industrial Constructions | Semester 1 | Design and construction of industrial plants. Design and construction of the basic installations of industrial buildings . |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270017 | Production Systems | Semester 2 | -- Production systems design. -- Production planning. -- Material requirements planning. -- Inventory management and supply logistics. -- Production-distribution systems. -- Production scheduling. -- Production control systems. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280026 | Electronic systems | Semester 1 | Microprocessors, microcontrollers, and peripherals. Microprocessor systems and DSPs. Programmable devices, including FPGAs |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280033 | Signal Conditioning and Ad Conversion | Semester 1 | Topic 1 ¿ Introduction to Interface Systems. Implementation of Basic Functions using Continuous-Time Circuits and Discrete-Time Circuits Topic 2 ¿ Second-order behaviors in amplifiers and their impact on interface circuits Topic 3 ¿ Sample and hold circuits Topic 4 ¿ Comparators Topic 5 ¿ Analog-Digital Converters Topic 6 ¿ Digital-Analog Converters Topic 7 ¿ Programmable gain amplifiers Practical Case 1 ¿ Impact of errors in circuits with operational amplifiers Practical Case 2 ¿ Comparator design for AD conversion Practical Case 3 ¿ AD converter design |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280074 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280001 | Physics I | Semester 1 | Mechanics, oscillations and waves. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550006 | The Finite Element Method | Semester 1 | I.- FEM in linear problems of Solid Mechanics I.1.- Introduction to FEM. Elastic problem and aspects of interest I.2.- FEM in problems of bars and beams I.3.- FEM in problems of plates and shells I.4.- Finite element formulation of the dynamic problem II.- FEM in non-linear problems: Nonlinear analysis with finite elements II.1.- Nonlinear problems in engineering II.2.- Residual equations and methods of solving non-linear equations II.3.- Non-linear finite element formulation |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630014 | Transportation and Distribution Networks | Semester 1 | BLOCK I: Flow in networks - The concept of graph - The flow model in networks - The minimum route problem - The maximum flow problem - The transport problem - Other flow models in networks BLOCK II: Transport and logistics networks - Location - Design of transport and distribution routes |
| M181 | Master's Degree in Chemical Engineering | 51810016 | Work Organization | Semester 2 | |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210051 | Chemical technology | Semester 1 | - Fundamentals of the chemical industry. Chemical process engineering. The role of the industrial engineering professional in the chemical and process industry. - Material and energy balances in systems relevant to process engineering. - Operations and processes in chemical engineering. Separation operations. Chemical reactors. - Introduction to the design and evaluation of sustainable chemical processes. |
| 199 | Degree in Telecommunications Technology Engineering | 1990048 | Advanced Network Architecture | Semester 1 | Advanced routing. Advances in IP. Multiprotocol switching. Ethernet-based access networks. Carrier Ethernet and virtual private network services. Multi-service networks and services. Advanced mobile networks. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920037 | The Finite Element Method | Semester 1 | I.- FEM in linear problems of Solid Mechanics I.1.- Introduction to FEM. Elastic problem and aspects of interest I.2.- FEM in problems of bars and beams I.3.- FEM in problems of plates and shells I.4.- Finite element formulation of the dynamic problem II.- FEM in non-linear problems: Nonlinear analysis with finite elements II.1.- Nonlinear problems in engineering II.2.- Residual equations and methods of solving non-linear equations II.3.- Non-linear finite element formulation |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940042 | Robotics Projects | Semester 1 | V Design/Development Methodology Robotic Systems Architecture Techniques for Robotics Projects Selection of Hardware and Software Components |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210092 | Project and Maintenance of Electrical Installations | Semester 2 | Design, construction, maintenance, and safety of electrical installations. Regulations and procedures related to electrical installation projects. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560047 | Monitoring and Action in Industrial Plants | Semester 2 | Data acquisition systems. Sensors and actuators. Virtual and synthetic instrumentation. Industrial communications. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960037 | Quantitative Decision-Making Tools | Semester 1 | 1. Modeling and optimization 2. Linear programming 3. Integer programming |
| M190 | Master's Degree in Civil Engineering (2019) | 51900040 | Special Construction Procedures | Semester 2 | BLOCK 1. Demolition and Demolition BLOCK 2. Planning, Execution and Specific Construction Machinery for Works: Roads, Railways, Bridges and Viaducts, Hydraulic, Sanitary and Maritime (taking into account the constructive singularities that may arise and the techniques applied for their treatment). BLOCK 3. Construction Waste Management |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210009 | Physics II | Semester 2 | Electromagnetism, Fundamentals of Thermodynamics. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280046 | Robotics Laboratory | Semester 1 | Robot control architecture. Robot control methods. Advanced robot programming. |
| M165 | Master's Degree in Thermal Energy Systems | 51650011 | Simulation and Optimization of Thermal Energy Systems | Semester 1 | Part I: Thermal Systems Optimization Lesson 1. Introduction to Simulation and Optimization of Thermal Processes Lesson 2. Basic Design Considerations Lesson 3. Introduction to Modeling and Simulation of Thermal Processes Lesson 4. Simulation of Thermal Processes Lesson 5. Optimization of Thermal Systems Lesson 6. Cost Estimation and Economic Analysis of Thermal Processes Lesson 7. Applications in the Design of Heat Exchangers Part II: Heat Exchanger Networks Lesson 8. Heat Exchanger Networks Part III: Simulation of Thermal Systems Lesson 9: Dynamic Simulation of Thermal Systems (EES) Lesson 10: Characterization of Thermal Systems Using Performance Curves Lesson 11: Dynamic Simulation of Thermal Systems (EXCEL) |
| 203 | Degree in Industrial Technology Engineering | 2030099 | Industrial and Technological Policy | Semester 2 | Market structures. Efficiency, competition, and regulation. Industrial property. |
| 199 | Degree in Telecommunications Technology Engineering | 1990073 | Mobile communications | Semester 2 | The mobile communications channel. Mobile Communications Systems. New Techniques in Mobile Communications. |
| 225 | Degree in Civil Engineering | 2250025 | Geotechnics | Semester 1 | Filtration networks. Soil as an elastic medium. Safety factors. Short- and long-term stability. Slope stability. Earth pressure. Retaining structures. Subsidence load. Settlement. Pile concepts. Regulations. |
| 225 | Degree in Civil Engineering | 2250011 | Mathematics expansion | Semester 1 | Knowledge of advanced aspects of Mathematical Analysis and its applications: Second-order linear differential equations. Systems of linear differential equations. Stability and phase planes. Fourier series and boundary problems in ordinary differential equations. Separation of variables method for solving partial differential equations. |
| 199 | Degree in Telecommunications Technology Engineering | 1990042 | Audio Systems | Semester 2 | Audio acquisition, digitization, measurement, and editing. Storage and transmission formats. Sound processors. |
| 208 | Degree in Chemical Engineering | 2080012 | Elasticity and Resistance of Materials | Semester 1 | Elasticity In this section of deformable solid mechanics, the behavior of elastic and linear solids is studied. Strength of Materials In this second section, the general model of the Theory of Elasticity is specified for the case of bar structures, resulting in a simplified one-dimensional model of great practical use. Both sections establish the theoretical aspects of the introduced analytical models and apply them to practical examples, training the ability to apply the learned concepts to new situations for a wide variety of typologies. TOPICS: 1. Stresses 1.1 Introduction. 1.2 The concept of stress. 1.3 Cauchy's lemma. 1.4 Internal equilibrium equations. 1.5 Coordinate transformation. 1.6 Intrinsic coordinates. 1.7 Principal stresses. 1.8 Extreme values of the intrinsic components. 2. Deformations 2.1 Introduction and hypothesis. 2.2 The strain tensor. 2.3 Compatibility equations. 2.4 Stress-strain correlation. 2.5 Integration of the displacement field. 2.6 Experimental measurement of strains (Ohmic extensometry). 3. Law of Behavior 3.1 Introduction. 3.2 The tensile test. 3.3 Generalized Hooke's law. 4. The elastic problem 4.1 Introduction. 4.2 General formulation. 4.3 Boundary conditions 4.4 Resolution procedures. 4.5 Planar problems. 5. Other aspects of deformable solids 5.1 Introduction. 5.2 Concept of work. Clapeyron's theorem. 5.3 The Saint-Venant principle. 5.4 Thermoelasticity. 5.5 Yield criteria. 6. Basic concepts of Strength of Materials 6.1 Introduction. 6.2 General approach to the bar model. 6.3 Stresses in the section. Internal forces. 6.4 External forces. 6.5 Equations of equilibrium. 7. Tension and bending in plane structures 7.1 Introduction. 7.2 Basic equations of plane structures. 7.2.1 Assumptions. 7.2.2 Compatibility equations. 7.2.3 Equations of behavior. 7.2.4 Stress calculation. 7.3 Comparison with the theory of elasticity. 7.4 Redefinition of stress calculation. 7.4.1 Solid sections. 7.4.2 Thin-walled sections. 7.5 Summary of equations. 7.6 Free nodes and supports. 7.7 Applications: continuous beams, pinned structures and frames. 7.8 Use of symmetry. 8. Integration of the equations. Stress laws and displacement calculation 8.1 Introduction. 8.2 Integration of the equilibrium equations. Internal stress laws. 8.3 Integration of the Compatibility-Behavior equations. 8.3.1 Mohr's theorems. 8.3.2 Principle of Virtual Forces 9. Structural design methods. The force method 9.1 Introduction. 9.2 Concepts of isostasy and hyperstaticity. 9.3 The force method. 10. Other aspects of interest 10.1 Introduction. 10.2 Design aspects. 10.3 Buckling of bars. 10.4 Bending and shear in two planes. 10.5 Free torsion. Solid and thin-walled sections Practices Practice 1. Tensile testing Practice 2. Ohmic extensometry Practice 3. Plane bending Practice 4. Torsion and buckling |
| 208 | Degree in Chemical Engineering | 2080015 | Thermodynamics | Semester 1 | S01 Initial Concepts S02 Partial Molar Magnitudes S03 Principles of Thermodynamics; Exergy S04 Formulation of the Thermodynamic Equations of State S05 Thermodynamic Potentials S06 Equilibrium and Stability S07 Deduction of the Thermodynamic Equations of State S08 Chemical Reactions S09 Combustion S10 Phase Equilibria S11 Forward Cycles S12 Reverse Cycles |
| M146 | Master's Degree in Industrial Engineering | 51460071 | Microsystems and Nanotechnologies | Semester 2 | THEMATIC BLOCKS 1. INTRODUCTION TO MICROSYSTEMS. 2. APPLICATIONS OF MICROSYSTEMS. 3. DESIGN AND MANUFACTURING A MICROSYSTEM. 4. INTRODUCTION TO NANOTECHNOLOGY. |
| M181 | Master's Degree in Chemical Engineering | 51810009 | Quality management | Semester 1 | Basic quality concepts. Regulations on the verification and control of facilities, products, and services. Global regulatory system. Quality management models and systems. ISO 9000, 14000, and 45000 families Audits, certifications, testing, and reports. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320002 | Aircraft calculation and aircraft systems | Semester 1 | --------------------- English Version : Preliminary aircraft sizing. Design and study of aircraft systems. Aerodynamic study of aircraft. Aircraft stability and control study. Aircraft structural study. Study of aircraft performance and propulsion. Concurrent engineering tools in aircraft design. Aircraft design optimization tools. --------------------- SPANISH: Preliminary aircraft sizing. Design and study of aircraft systems. Aerodynamic study of aircraft. Study of aircraft stability and control. Aircraft structural study. Study of aircraft performance and propulsion. Concurrent engineering tools in aircraft design. Aircraft design optimization tools. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320005 | Air Transport Complements | Semester 1 | TOPIC 1: DEMAND MODELS Concept of elasticity. Elasticity in air transport. Types of models and variables. Constant elasticity models. Non-constant elasticity models. Fitting the constant elasticity model. Interpretation of the fit. Collinearity of explanatory variables. Gravity models. Practical cases of demand models. Dynamic pricing. TOPIC 2: CHOICE MODELS Choice of transport mode. The logit model. Concept of utility. Types of variables on which utility depends. Fundamentals of RUM theory. Practical case of a modal choice model. Model fit. Interpretation of results. Estimating the cost of time for the user. Types of surveys. TOPIC 3: DETERMINISTIC QUEUING ANALYSIS Definition of a queuing system. Counting process. Poisson process. Properties of the Poisson distribution. The aircraft and passenger arrival process. Cumulative curves. Types of queuing analysis. Queue formation. Little's formula. Queue reduction. Group service. Airport capacity. Simulation of a Poisson process. Simulation of a queue with one server. Simulation of a queue with several servers. Analytical model for constant service time: application to landings/takeoffs. TOPIC 4: QUEUING THEORY Standard notation. The M/M/1 queue. The M/M/c queue: several servers. The M/M/infinity queue: unlimited service. The M/G/1 queue: Pollaczek-Khintchine formula. The M/M/c/c queue: Erlang formula. Approximations for G/G/1 and G/G/c queues. TOPIC 5: APPLICATIONS OF LINEAR PROGRAMMING IN AIR TRANSPORT Fundamentals of linear programming and main results. Fleet assignment. Aircraft rotation. Crew assignment. Work shift scheduling. Design of a passenger transport network. Assignment of boarding gates: the assignment problem. Freight transportation network: the transportation problem. Analysis of airport efficiency. BIBLIOGRAPHY: ¿Airline operations and Scheduling¿ M. Bazargan (2005). Ashgate. ¿Operations Research in Space and Air¿ TA Ciriani, G. Fasano, S. Gliozzi, and R. Tadei (2003) Kluwer. Queuing Methods for Services and Manufacturing (1997) RW Hall. Prentice Hall. Fundamentals of Queuing Theory D. Gross, C. Harris. (1998) Wiley. ¿An Introduction to Queuing Theory: Modeling and Analysis in Applications¿ (2008) UN Bhat. |
| 208 | Degree in Chemical Engineering | 2080060 | Chemical Plant Engineering | Semester 2 | LESSON 1.- ORGANIZATION OF AN ENGINEERING FIRM LESSON 2.- ORGANIZATION FOR THE EXECUTION OF ENGINEERING WORK. LESSON 3.- ENGINEERING DOCUMENTS OF A CHEMICAL PLANT PROJECT. LESSON 4.- CODES OF RECOGNITION PRESTIGE AND ENGINEERING STANDARDS. LESSON 5.- SAFETY ASPECTS IN THE DESIGN OF CHEMICAL PLANTS. LESSON 5.- MANAGEMENT OF AUTHORIZATIONS OF AN ENGINEERING PROJECT LESSON 6.- INDUSTRIAL REGULATIONS AND THEIR APPLICATION IN THE DESIGN OF CHEMICAL PLANTS. Case studies: At least one case study, Crisis Management in Industry, will be scheduled, with the possibility of proposing a second case study to be defined, at the discretion of the instructors. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210020 | Applied Thermodynamics | Semester 2 | Section 1. CHEMICAL POTENTIAL. EQUILIBRIUM AND STABILITY IN COMPOSITE SYSTEMS Section 2. DEPENDENCE OF THERMODYNAMICS FUNCTIONS ON COMPOSITION Section 3. THERMODYNAMICS OF MIXTURES Section 4. THERMODYNAMICS OF MIXTURES: APPLICATIONS Section 5. PSYCHROMETRIC THERMODYNAMICS Section 6. DESALINATION THERMODYNAMICS Section 7. CHEMICAL REACTIONS Section 8. THERMODYNAMICS OF COMBUSTION AND FUEL REPLENISHMENT Section 9. EXTENSION OF THERMODYNAMICS CYCLES LABORATORY PRACTICES |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210033 | Projects | Semester 2 | Methodology, organization and project management. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210040 | Hydraulic Power Plants | Semester 2 | Hydraulic power plants, pumping stations, technical and economic aspects of hydroelectric generation. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210143 | Intelligent Maintenance Systems | Semester 2 | Advanced systems and techniques to support (and optimize) maintenance management and the management of the resources required for its execution |
| 225 | Degree in Civil Engineering | 2250023 | Structure Calculation | Semester 1 | - Plane structures with pinned joints - Rigid joint structures. Direct stiffness method - Introduction to the study of global buckling of bar structures - Introduction to dynamic structural design - Introduction to the finite element method - Thick and thin plates |
| 225 | Degree in Civil Engineering | 2250018 | Mathematical methods | Semester 2 | Lesson 1. Introduction to numerical analysis. Errors. Conditioning and stability. Lesson 2. Systems of linear equations and eigenvalues. Determined compatible systems. Sparse matrices. Overdetermined systems. Power method for calculating eigenvalues. Lesson 3. Polynomial and trigonometric interpolation . The interpolation polynomial. Piecewise polynomial interpolation. Trigonometric interpolation and the fast Fourier transform. Application to series and the Fourier integral transform. Lesson 4. Quadrature and numerical differentiation. Elementary quadrature rules. Gaussian quadrature. Differentiation formulas. Lesson 5. Nonlinear equations and optimization. Zeros of functions in one variable. Optimization in one variable. Unconstrained optimization in several variables. Lesson 6. Ordinary and partial differential equations . Initial value problems. Linear and nonlinear boundary problems. Partial differential equations. |
| 225 | Degree in Civil Engineering | 2250071 | Civil Construction Complements (TS, HL) | Semester 1 | - Prestressed concrete technology. - HP regulations and calculation bases. - Strength verification criteria, fitness for service, and durability. - Execution control of HP structures. - Construction and maintenance of: road and airport pavements and road surfaces, railway infrastructure; storage facilities and above-ground and underground pipelines. - Structural dynamics. - Shell structures. - Plate buckling. - Composite structure technology. - Regulations and calculation bases for composite structures. - Strength and instability limit states of composite beams and supports. - Connectors. - Fitness for service. - Control, protection, and maintenance of steel and composite structures. - Recommendations for design and maintenance. - Evaluation of public works projects. - Tendering and contracting of public works. - Legal framework. - Task and time scheduling. - PERT and CPM. - Project control. - Cost control. - Human resources. |
| 225 | Degree in Civil Engineering | 2250068 | Computational Mathematics | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210031 | Mechanics of Composite Materials (IRM) | Semester 2 | Definition and classification. Manufacturing of composite materials. Receiving and quality control of composite materials. Laminate behavior. Properties and failure criteria. General theory of laminates. In-service behavior. Applications. Adhesive and mechanical bonds. |
| 225 | Degree in Civil Engineering | 2250032 | Sanitary Engineering | Semester 1 | Water management cycle. Drinking water treatment plants (DWTPs) and urban wastewater treatment plants (WWTPs): sizing and operation. Supply and sanitation systems |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210032 | Quantitative Management Methods (OGSP, OGCS) | Semester 1 | Linear Programming. Network Flow. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270060 | Industrial Complexes | Semester 2 | Industrial urban planning. Industrial complexes. Industrial estates and technology parks. Design of industrial complexes and typology of industrial construction elements. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210006 | Rational Mechanics Complements | Semester 1 | Extension to Kinematics and Vectorial Dynamics of Rigid Bodies. Analytical Formulation of Mechanics. Extension to Impulsive Dynamics. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280013 | Electronics Fundamentals | Semester 1 | Devices. Polarization. Amplifiers. The Operational Amplifier and its Applications. Logic Families. Introduction to Digital Electronics. Introduction to Communications |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270003 | Mathematics I | Semester 1 | Linear algebra, geometry and complex numbers. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280010 | Mathematics III | Semester 2 | 1. Functions of several variables. Differentiability. 2. Optimization of scalar fields. 3. Differential geometry. 4. Multiple integrals. 5. Line integrals. 6. Surface integrals. 7. Partial differential equations. 1. Functions of several variables. Differentiability. Scalar and vector fields. Limits and continuity. Partial derivatives and directional derivatives. Differentiability of scalar and vector fields: gradient vector and Jacobian matrix. Higher-order derivatives. Implicit differentiation and implicit function theorem. 2. Optimization of scalar fields. Quadratic forms and real symmetric matrices. Relative extrema of scalar fields. Absolute extrema of scalar fields. Lagrange multipliers. 3. Differential geometry. Regular curves. Frenet trihedron. Parameterized surfaces. First and second fundamental forms. Curvatures. 4. Multiple integrals. Double integrals. Change of variables: polar coordinates. Triple integrals. Change of variables: cylindrical and spherical coordinates. 5. Line integrals. Line integral. Conservative fields. Potential. Curl. Exact differential equations. Vector calculus in the plane: Green's theorem. 6. Surface integrals. Surface integrals. Divergence. Vector calculus in space: Stokes's theorem and Gauss's theorem. 7. Partial differential equations. Introduction. First-order partial differential equations. Laplace's, wave, and heat equations. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280028 | Power Electronics | Semester 2 | Advanced knowledge of power electronics and converters: topologies, control techniques. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280057 | Robotics Expansion | Semester 2 | CONTENT: Robotics extension. THEMATIC BLOCKS: I. Introduction to autonomous systems. II. Mobile robots - Motion planning. - Localization. III. Manipulator arms - Motion planning. - Interaction with the environment. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560010 | Physics Extension | TO | Specific content according to the verification report: Kinematics and vector dynamics of points, particle systems, and rigid bodies. Analytical mechanics. Impulsive dynamics. Electromagnetism. Maxwell's equations. Electromagnetic radiation and principles of optics. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560062 | Nuclear Technology | Semester 2 | Thematic sections: -Nuclear reactions -Nuclear reactor physics protection -Radiation waste treatment |
| M146 | Master's Degree in Industrial Engineering | 51460065 | Advanced Materials Mechanics | Semester 2 | PART 1: MECHANICS OF COMPOSITE MATERIALS (24H) BLOCK 1: ANISOTROPIC ELASTICITY (9h) Topic 1.1. Introduction. Topic 1.2. Formulation of the elastic problem in anisotropic materials. Topic 1.3. Basic elastic problems for a cylindrical solid. Topic 1.4. The Finite Element Method applied to anisotropic materials. Topic 1.5. Plane Elasticity and its applications. BLOCK 2: COMPOSITE MATERIALS (9h) Topic 2.1. Introduction. Topic 2.2. Mechanical behavior of a sheet. Topic 2.3. Mechanical characterization of a sheet Topic 2.4. Mechanical behavior of a laminate. Topic 2.5. Interlaminar stresses. Topic 2.6. Analysis of structural elements of composite material. BLOCK 3: FAILURE OF COMPOSITE MATERIALS (6h) Topic 3.1. Introduction. Failure mechanisms in composite materials. Topic 3.2. Failure criteria at the lamina level. Topic 3.3. Laminate failure. Degradation models. Topic 3.4. Micromechanical aspects of composite material failure. PART 2: NANOMECHANICS OF SOLIDS (16h) BLOCK 4: NANOMECHANICS OF SOLIDS (16h) Topic 4.1. Introduction to crystal lattices and their defects. Topic 4.2. Multiscale modeling of materials. Computational methods. Topic 4.3. Interatomic potentials. Topic 4.4. Energy stored in a crystal with defects. |
| 197 | Degree in Aerospace Engineering | 1970046 | Aerodynamics II | Semester 1 | Linearized potential theory of wings in the subsonic regime. Wave equation. Linearized potential theory of airfoils in the supersonic regime: interference. Linearized potential theory of wings in the supersonic regime. Forces on slender bodies. |
| 197 | Degree in Aerospace Engineering | 1970025 | Propulsion Fundamentals | Semester 1 | Introduction to propulsion. Propeller propulsion. Jet propulsion in non-autonomous systems. Jet propulsion in autonomous systems. |
| 199 | Degree in Telecommunications Technology Engineering | 1990032 | Integrated Electronics | Semester 2 | CMOS technology. Integrated circuit design. Passive components. analog integrated building blocks |
| 197 | Degree in Aerospace Engineering | 1970027 | Airport Electrical Installations | Semester 1 | - Low Voltage (LV) Conduits. - High Voltage (HV) Underground Power Lines. - High Voltage (HV) Overhead Power Lines. - Short-Circuit Currents. - Overcurrent Protection of Facilities. Design of Protection Against Overloads and Short-Circuits. - Protection of Persons from Direct and Indirect Contact in Low Voltage (LV) Installations. Selection of Protection for Persons from Direct and Indirect Contact in Low Voltage (LV) Installations. - Transformer Stations. Grounding Installations in Transformer Stations. - Protection of Persons in High Voltage (HV) Installations. Design of Protection for Persons from Direct and Indirect Contact in High Voltage (HV) Installations. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830015 | Industrial Security | Semester 1 | After a general introduction, the course will be divided into the following fundamental sections: 1. Overview of Industrial Safety. 2. The different stages in the implementation of an ES: Hazard Identification Techniques. 3. The different stages in the implementation of an ES: Consequence Analysis. 4. Quantitative Risk Analysis (RCA). 5. Risk Reduction Techniques applied to the design of chemical plants. 6. Emergency Plan. Inside and outside the factory. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940041 | Automation Projects | Semester 1 | Automation project - Project phases - Approach, equipment selection - Documentation, Technical Reports: Implementation of the automation project - Programming structure - Programming - Simulators - Communications and HMI |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940049 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960039 | Industrial Innovation and Prevention | Semester 2 | INDUSTRIAL PREVENTION BLOCK I. Legislative bases of Occupational Risk Prevention BLOCK II. General introduction to Safety BLOCK III. General introduction to Industrial Hygiene BLOCK IV. General introduction to Ergonomics and Applied Psychosociology BLOCK V. Management tools and practical applications INNOVATION BLOCK VI. CONCEPT OF INNOVATION BLOCK VII. INTRODUCTION TO VALUE ANALYSIS BLOCK VIII. IDENTIFICATION, CHARACTERIZATION AND DEFINITION OF VALUE ANALYSIS PROJECTS BLOCK IX. CUSTOMER AND COST ANALYSIS BLOCK X. FUNCTIONAL ANALYSIS BLOCK XI. MULTICRITERIA ANALYSIS |
| 225 | Degree in Civil Engineering | 2250043 | Surface and Groundwater Hydrology | Semester 1 | Hydrological cycle Hydrological basin Hydrogeology Groundwater harvesting techniques Aquifer behavior models Legal regulation of groundwater. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980039 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 197 | Degree in Aerospace Engineering | 1970006 | Mathematics II | Semester 1 | Calculus in one and several variables. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270054 | Business Management Systems | Semester 1 | T1. Purchasing and Supplier Area. T2. The Production Area - Manufacturing. T3. The Commercial Area. T4. Sales Margins. Sales Volumes. T5. Cost Structure. Results. T6. Case Study |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270069 | Industrial Metrology | Semester 2 | PART 1 Introduction to metrology Metrology and business. Standardization. Certification. Testing. Calibration. Inspection. Accreditation. The metrology laboratory. The measuring instrument. Measurement errors. The international system of units. Measurement uncertainty. Final expression of the measurement result PART 2 Dimensional metrology Fits and tolerances. Measuring instruments. Gauges. Surface roughness. Geometric tolerances. Measurement of threads and gears. Functional dimensioning PART 3 Metrology of other quantities Electrical metrology. Pressure measurement. Temperature measurement. Torque measurement |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320013 | Applied orbital mechanics | Semester 2 | Computational Orbital Mechanics. Space Surveillance. Orbit Determination. Orbital Disturbances. |
| 203 | Degree in Industrial Technology Engineering | 2030087 | Thermal Process Engineering | Semester 1 | Topic 1. General Introduction to Thermal Process Engineering. Basic Design Considerations Topic 2. Introduction to modeling and simulation of thermal processes Topic 3. Introduction to Optimization Topic 4. Cost Estimation and Economic Analysis of Thermal Processes Topic 5: Applications on mass and energy balance in Thermal Processes Topic 6: Fundamentals of phase change heat transfer: Condensation and Boiling Topic 7: Applications in the design of phase change heat exchangers. Phase change of multicomponent mixtures. Topic 8: Applications in the design of thermal equipment: Evaporators Topic 9: Applications in the design of cold production equipment |
| M143 | Master's Degree in Aeronautical Engineering | 51430033 | Aerospace Production | Semester 2 | The Supply Chain in the Aeronautical Industry. Production Management Systems in the Aeronautical Industry. Lean Manufacturing. Final Aircraft Assembly Lines (FAL) |
| 197 | Degree in Aerospace Engineering | 1970002 | Computing | TO | Computer Fundamentals. Algorithms. Programming. Introduction to operating systems, databases, and software with applications in engineering. Subject Unit I. Computer Fundamentals. Subject Unit II. Algorithms. Subject Unit III. Programming Fundamentals. |
| 199 | Degree in Telecommunications Technology Engineering | 1990046 | Electronic Technology | Semester 2 | Printed circuit board design, manufacturing, and testing. Circuit design for power supply and electrical energy conversion for telecommunications and computing applications. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270031 | Modeling and Simulation of Industrial Systems | Semester 2 | Stochastic processes. Queuing theory. Simulation. Application to modeling and problem solving in organizational engineering. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940032 | Smart Building Automation | Semester 1 | The course is divided into three thematic sections: Thematic Section I (Building Installations, Current Regulations, and Home Automation Projects): This section describes the existing installations in buildings and presents the current regulations in Spain related to their automation. The course covers the implementation of the home automation project, construction management, completion certification, and maintenance. Thematic Section II (Building Automation Technologies): This section focuses on presenting the main home automation technologies and microgrid systems used, with particular emphasis on those that are typically used for the automation of large buildings, as well as the associated control problems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210047 | Electrical technology | Semester 1 | 1. DESCRIPTION OF ELECTRICAL SYSTEMS 2. ELECTRICAL POWER GENERATION AND MARKETS 3. ELECTRICAL MACHINES 4. ELECTRICAL POWER TRANSPORTATION 5. SHORT CIRCUITS CALCULATION 6. MEDIUM AND LOW VOLTAGE DISTRIBUTION SYSTEM |
| 208 | Degree in Chemical Engineering | 2080045 | Thermal Process Engineering | Semester 1 | Topic 1. General Introduction to Thermal Process Engineering. Basic Design Considerations Topic 2. Introduction to modeling and simulation of thermal processes Topic 3. Introduction to Optimization Topic 4. Cost Estimation and Economic Analysis of Thermal Processes Topic 5: Applications on mass and energy balance in Thermal Processes Topic 6: Fundamentals of phase change heat transfer: Condensation and Boiling Topic 7: Applications in the design of phase change heat exchangers. Phase change of multicomponent mixtures. Topic 8: Applications in the design of thermal equipment: Evaporators Topic 9: Applications in the design of cold production equipment |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040023 | Cybersecurity Management | Semester 1 | Block 1. Basic concepts of cybersecurity Block 2. Basic regulations applicable to cybersecurity Block 3. Cybersecurity Management Systems |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280005 | Chemistry | Semester 1 | DESCRIPTORS: Basic concepts of chemistry. Kinetics, thermodynamics and equilibrium. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920036 | The Boundary Element Method | Semester 1 | BLOCK 1: INTRODUCTION TO THE BOUNDARY ELEMENT METHOD (BEM) (9h) Topic 1.1. Introduction to the basic concepts of the method. Topic 1.2. BEM approach to potential problems and its implementation in a computational code. Topic 1.3. Applications. BLOCK 2: BEM APPLIED TO POTENTIAL AND ELASTIC PROBLEMS (15.5h) Topic 2.1. Calculation of singular integrals. Topic 2.2. The Symmetric Galerkin BEM. Topic 2.3. BEM approach to static elastic problems and its implementation in a computational code. Topic 2.4. Applications. BLOCK 3: BEM APPLIED TO ELASTIC WAVE PROPAGATION PROBLEMS (15.5h) Topic 3.1. Wave propagation. Topic 3.2. 2D Formulation of the FEC in the Frequency Domain. Section 3.3. 3D Formulation of the FEC in the Frequency Domain. Section 3.4. 3D Formulation of the FEC in the Time Domain. Section 3.5. Applications. |
| M146 | Master's Degree in Industrial Engineering | 51460081 | Electronic Systems for Aerospace Applications | Semester 2 | It has four thematic blocks: Block I. Testing and qualification of electronic components Block II. Testing and qualification of complex electronic systems Block III. Design for qualification of programmable electronic devices for aeronautics and space Block IV. Design of aerospace systems |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980033 | Combustion in Thermal Engines | Semester 2 | Part 1 Basic considerations of combustion Part 2 Fundamentals of combustion Part 3 Combustion in MCIA Part 4 Combustion in TG Part 5 Combustion in TV Part 6 Emissions Part 7 Numerical methods in combustion |
| 208 | Degree in Chemical Engineering | 2080050 | Fuel Technology | Semester 1 | CHAPTER 1. INTRODUCTION TO ENERGY PRODUCTION SOURCES TOPIC 1.- FROM PRIMARY ENERGY TO FINAL ENERGY. WORLD ENERGY OUTLOOK TOPIC 2.- ENERGY IN THE EUROPEAN UNION AND SPAIN CHAPTER 2. FOSSIL FUELS TOPIC 3.- COAL TOPIC 4.- OIL TOPIC 5.- NATURAL GAS CHAPTER 3. RENEWABLE FUELS TOPIC 6.- BIOENERGY TOPIC 7.- BIOFUELS CHAPTER 4. FUEL PRODUCTION TECHNOLOGIES TOPIC 8.- CHARACTERIZATION OF CRUDE OIL TOPIC 9.- CRUDE OIL PREPARATION TOPIC 10.- DISTILLATION TOPIC 11.- HDS AND REFORMING TOPIC 12.- VACUUM DISTILLATION TOPIC 13.- CRACKING TOPIC 14.- HYDROCRACKING AND MIDDLE DISTILLATES TOPIC 15.- AUXILIARY SERVICES. LUBRICANTS TOPIC 16.- ENVIRONMENTAL ASPECTS OF REFINING CHAPTER 5. FUEL USE PROCESSES TOPIC 17.- COMBUSTION TECHNOLOGIES (I) TOPIC 18.- COMBUSTION TECHNOLOGIES (II) TOPIC 19.- HYDROGEN AS AN ENERGY VECTOR AND FUEL CELLS TOPIC 21.- ENERGY STORAGE TOPIC 22.- FORMATION OF SOx AND NOx. TOPIC 23.- PRIMARY AND SECONDARY MEASURES FOR NOx CONTROL TOPIC 24.- COMBUSTION GAS DESULFURIZATION TOPIC 25.- PARTICLE FORMATION AND FLY ASH. ABATEMENT TECHNOLOGIES TOPIC 26.- CO2 CAPTURE, TRANSPORT AND STORAGE TOPIC 27.- TOWARDS A DECARBONIZED ECONOMY |
| 225 | Degree in Civil Engineering | 2250051 | Urban Services | Semester 1 | 1. URBAN WATER SUPPLY NETWORKS 2. URBAN SANITATION NETWORKS 3. PUBLIC LIGHTING 4. ELECTRICAL NETWORKS |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280077 | Home automation | Semester 2 | The course content will be divided into three main thematic blocks: - Block I: Introduction to the basic concept of home automation networks in buildings. The basic characteristics of home automation systems will be explained and detailed, including their fundamental elements and the relationships between them. The structure and organization of basic installations in smart homes and buildings in general will be detailed. - Block II: Description of the main home automation technologies available on the market, along with the protocols used. - Block III: Introduction to service robotics and the concept of smart cities. |
| 225 | Degree in Civil Engineering | 2250019 | Material resistance | Semester 2 | Internal forces. Tension and bending in solid and thin-walled sections. Stress diagrams, displacement calculations. Beams and frames. Instability. Torsion. |
| M181 | Master's Degree in Chemical Engineering | 51810019 | Industrial Security | Semester 1 | After a general introduction, the course will be divided into the following fundamental sections: 1. Overview of Industrial Safety. 2. The different stages in the implementation of an ES: Hazard Identification Techniques. 3. The different stages in the implementation of an ES: Consequence Analysis. 4. Quantitative Risk Analysis (RCA). 5. Risk Reduction Techniques applied to the design of chemical plants. 6. Emergency Plan. Inside and outside the factory. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550013 | Nonlinear Continuum Mechanics | Semester 1 | BLOCK 1: Introduction to Nonlinear Continuum Mechanics. Lesson 1.- A first contact with nonlinear deformable solid mechanics. Lesson 2.- Contact boundary condition in the elastic problem. BLOCK 2: The linear and nonlinear elastic solid with large deformations. Lesson 3.- Kinematics of deformable solids Lesson 4.- Conservation principles Lesson 5.- Behavioral relation Lesson 6.- Formulation of the elastic problem Lesson 7.- Variational structure of the elastic problem Lesson 8.- Viscoelastic materials BLOCK 3: The perfect elastoplastic solid with small deformations. Lesson 9.- Plasfication criteria Lesson 10.- The perfect elastoplastic model Developed program BLOCK 1: Introduction to Nonlinear Continuum Mechanics. Lesson 1.- A first contact with nonlinear deformable solid mechanics. 1.1 Introduction. 1.2 Review of the elastic problem. 1.3 Sources of nonlinearity. 1.4 Boundary conditions. Lesson 2.- Contact boundary condition in the elastic problem. 2.1 Introduction. 2.2 Frictionless contact (2D and 3D) 2.3 Frictional contact (2D and 3D) 2.4 Numerical solution methodologies in Finite Element codes. BLOCK 2: The linear and nonlinear elastic solid with large deformations. Lesson 3.- Kinematics of deformable solids 3.1.- Configuration space. Motion, velocity and acceleration 3.2.- Strain gradient 3.3.- Strain tensors 3.4.- Polar decomposition of the strain gradient 3.5.- Physical interpretation of the components of the strain tensor 3.6.- Strain tensors under the hypothesis of small deformations and displacements 3.7.- Time derivative of the strain tensors Lesson 4.- Conservation principles 4.1.- Stress tensors in large displacements 4.2.- Fundamental law of conservation 4.3.- Conservation of mass (CM) 4.4.- Theorem of variation of the momentum (VCM) 4.5.- Theorem of variation of the kinetic momentum (VMC) 4.6.- Conservation of energy (CE) 4.7.- Second law of thermodynamics 4.8.- Compliance with the principles of conservation. Green-Naghdi-Rivlin theorem 4.9.- Entropy production. Gibbs condition Lesson 5.- Behavioral relation 5.1.- Behavioral relation. Typologies of materials 5.2.- Behavioral relation for elastic materials 5.2.1.- Conditions for the behavioral relation 5.2.2.- Behavioral relation as a function of the free energy function 5.2.3.- Elastic tensors 5.2.4.- Spatial version of the behavioral relation for elastic materials in isothermal processes 5.2.5.- The elastic material as a hyperelastic material. Strain energy density function 5.3.- Elastic materials with symmetries 5.3.1.- Homogeneous elastic materials 5.3.2.- Isotropic elastic materials 5.4.- Hyperelastic materials 5.4.1.- Isotropic hyperelastic materials 5.4.2.- Behavior of the strain energy density function for large deformations 5.4.3.- Classical hyperelastic models Lesson 6.- Formulation of the elastic problem 6.1.- Strong statement of the problem of nonlinear elastodynamics 6.2.- Weak statement of the problem of nonlinear elastodynamics 6.3.- Mathematical basis of linear elastostatics Lesson 7.- Variational structure of the elastic problem 7.1.- Hamiltonian structure of nonlinear elastodynamics 7.2.- The Minimum Potential Energy Theorem in elastostatics linear 7.3.- Other variational principles BLOCK 3: The perfect elastoplastic solid with small deformations. Lesson 8.- Plasmid criteria 8.1.- Introduction. 8.2.- Definition of the plasmid criterion. 8.3.- Experimental evidence. 8.4.- General characteristics. 8.5.- Tresca criterion. 8.6.- von Mises criterion. 8.7.- Comparison with experiments. Lesson 9.- The perfect elastoplastic model 9.1.- The one-dimensional case. Basic postulates. 9.2.- The three-dimensional case. 9.3.- Equivalent stress and equivalent plastic strain. 9.4.- Inverse behavior law. 9.5.- Uniqueness theorem. 9.6.- Plastic collapse. 9.7.- Limit analysis 9.8.- Uniqueness in Limit Analysis. 9.9.- Limit analysis of plane problems. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550001 | Application of Computational Methods to Mechanical Design | Semester 2 | The contents of the subject are structured in four blocks: A. DYNAMICS: which covers objectives 5) and 6). B. PLASTICITY: which includes objective 3). C. FRACTURE AND FATIGUE MECHANICS: which includes objectives 1), 2) and 4). D. CONTACT: which considers objective 7). |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600013 | Mobile and Service Robotics | Semester 1 | INTRODUCTION MOBILE ROBOTICS PLANNING POSITION ESTIMATION SERVICE APPLICATIONS |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630003 | Efficiency and productivity | Semester 2 | Efficiency analysis Productivity measurement Technological change in organizations Advanced data envelopment analysis methods Advanced multicriteria methods Advanced multiobjective optimization |
| 197 | Degree in Aerospace Engineering | 1970041 | Aircraft Engines | Semester 2 | 1. INTRODUCTION Description of turbojet, turbofan, turboprop, turboshaft and reciprocating engine as propulsion systems. Thrust for each of these engines. Definition of specific thrust consumption, dimensionless specific consumption and dimensionless thrust. PART I: AVIATION ENGINES WITH GAS TURBINES. COMPRESSOR- 2 JETS ANALYSIS OF IDEAL CYCLES Components: Diffuser, Compressor, Fan, Propeller, Combustion chamber, Turbine, By-pass duct, By-pass mixer, Secondary burner, Propulsion nozzle, Industrial TG exhaust. Cycles: Turbojet, Turbojet with after-combustion, Turbofan with separated flow, Turbofan with mixed flow, Turboprop, Turboshaft 3 ANALYSIS OF IRREVERSIBILITIES IN COMPONENTS Components: Diffuser, Compressor, Fan, Propeller, Combustion chamber, Turbine, By-pass duct, By-pass mixer, Secondary burner, Propulsion nozzle, Industrial TG exhaust. 4 ANALYSIS OF REAL CYCLES Cycles: Turbojet, Turbojet with after combustion, Turbofan with separated flow, Turbofan with mixed flow, Turboprop, Turboshaft 5 INTRODUCTION TO THE OPTIMIZATION OF PROPULSION PLANTS Turbojet Optimization Optimization of Mixed Flow Turbofan Optimization of Separated Flow Turbofan Optimization of Turboprop 6 COMPONENT ANALYSIS Components: Diffusers Nozzles Axial compressors and "Fan" Centrifugal compressors Axial turbines Combustion chambers and secondary burners Ducts and mixers. |
| M181 | Master's Degree in Chemical Engineering | 51810010 | Air Pollution Control Engineering | Semester 1 | Analysis of industrial emissions. Definition of BACT. Applications of abatement techniques. Cross-media effects. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210028 | Mathematics applied to engineering | Semester 1 | Knowledge of advanced aspects of mathematical analysis and its applications to industrial engineering. Differential equations and systems of equations. Partial differential equations. Examples from engineering. |
| 199 | Degree in Telecommunications Technology Engineering | 1990066 | Television | Semester 1 | Video and television systems. Encoding, compression, rendering, broadcasting, distribution, and management of multimedia content. Gap-fillers. |
| 199 | Degree in Telecommunications Technology Engineering | 1990027 | Operating systems | Semester 1 | Operating Systems Architecture. Distributed Operating Systems. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900039 | Dams and Reservoirs | Semester 1 | Topic 1 - Introduction. Historical overview of the various accidents and events that have served to develop dam engineering Topic 2 - Dam typology. Dam typologies based on their different characterizing elements. Topic 3 - Dams and the terrain. Aspects of the terrain to be taken into account when designing a dam; terrain improvement techniques. Topic 4 - Reservoir Criteria and Projects . General Issues. Planning. Project. Construction. Topic 5 - Dam Calculation . Acting Forces. Stability of Gravity Dams, Pre-dimensioning. Sliding Stability of Vault Dams, Gravity Dams, Stress Calculation. Lightened Dams. Loose Material Dams. Topic 6.- Spillway design: Spillway typology, hydraulic foundations, designs of the different parts of a spillway Topic 7.- Dam construction: Construction aspects of the different types of dams Topic 8.- Auscultation of dams, reservoirs and ponds Variables to be auscultated, auscultation instruments, data collection and data interpretation Topic 9.- Safety of dams and ponds Fundamental aspects of dam safety; regulations to be applied; dam categories Topic 10.- Operation of dams, ponds and reservoirs: General aspects of dam operation. Operating standards. Emergency plans Topic 11.- Environmental aspects in the design and construction of dams and reservoirs: Aspects to be taken into account, corrective measures, preventive measures and compensatory measures |
| M190 | Master's Degree in Civil Engineering (2019) | 51900010 | Design of Water Treatment Plants | Semester 1 | Water purification methods. Drinking water treatment. Water treatment plant calculations. Management and operation of water treatment systems. Water disposal and reuse. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900043 | Remote Sensing in Civil Engineering Works | Semester 2 | 1. Introduction to Remote Sensing 2. Physical Principles 3. Sensors and Satellites. Software 4. Digital Imaging 5. Visual Interpretation and Analysis of Images: Corrections and Enhancements 6. Information Extraction and Data Verification 7. The GIS Environment for Remote Sensing 8. The LIDAR System 9. RADAR Imaging and Differential Interferometry (DinSAR) 10. Specific Applications of Remote Sensing to Civil Engineering |
| 203 | Degree in Industrial Technology Engineering | 2030045 | Control and Instrumentation of Chemical Processes | Semester 2 | Dynamic characterization, controllability, PID and advanced control, sensors, final control elements, control system hardware. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210061 | Degradation of Materials and Non-Destructive Testing (IRM) | Semester 1 | THEMATIC BLOCK I. DEGRACATION OF MATERIALS Topic 1. CONCEPT AND IMPORTANCE OF CORROSION. Concept and importance of corrosion. Classification of corrosion. Topic 2. HIGH TEMPERATURE CORROSION. Introduction. Tendency to oxidation. Oxide films. Mechanisms of oxide film growth. Oxide growth kinetics. Protective oxides and high temperature alloys. Topic 3. THEORETICAL BASIS OF AQUEOUS CORROSION. Similarity of corrosion with dry cell. Definition of anodes and cathodes. Electrochemical potentials. Thermodynamics of corrosion. Corrosion cells. Nernst equation. Electrochemical series and galvanic series. Topic 4. CORROSION RATE. PASSIVITY Corrosion rate. Polarization. Types of polarization. Determination of corrosion rate. Passivity. Topic 5. TYPES OF CORROSION. Uniform attack. Galvanic corrosion. Crevice corrosion. Pitting corrosion. Intergranular corrosion. Erosion corrosion. Cavitation. Fretting corrosion. Stress corrosion cracking. Fatigue corrosion. Hydrogen damage. Topic 6. ATMOSPHERIC CORROSION. Atmospheric corrosion. Corrosion mechanism. Influencing factors. Types of atmospheres. Topic 7. CORROSION OF SUBMERGED METALS. Introduction. Marine corrosion. Corrosion in natural waters. Corrosion in acidic and basic environments. Topic 8. CORROSION OF BURIED STRUCTURES. Introduction. Corrosion of buried metals. Characteristics. Corrosion processes. Factors. Stray current corrosion. Topic 9. DEGRADATION OF POLYMERIC MATERIALS. Topic 10. DEGRADATION OF CERAMIC MATERIALS. THEMATIC BLOCK II. NON-DESTRUCTIVE TESTING Topic 11. Introduction. NDT methods. Topic 12. Replication microscopy. Topic 13. Leak testing. Topic 14. Liquid penetrant testing. Topic 15. Magnetic testing: Particles and magnetic fields. Topic 16. Electric current testing: disturbance, induction. Topic 17. Microwave inspection. Topic 18. Ultrasonic inspection. Topic 19. Radiographic inspection. Topic 20. Thermal inspection. LABORATORY PRACTICES PRACTICE 1. Uniform corrosion PRACTICE 2. Importance of the medium in corrosion processes PRACTICE 3. Passivity (Faraday experiment) PRACTICE 4. Galvanic series in simulated seawater PRACTICE 5. Determining if a stainless steel is sensitized PRACTICE 6. Visualization of cold deformed areas PRACTICE 7. Copper electrodeposition on stainless steel |
| 203 | Degree in Industrial Technology Engineering | 2030092 | Automation and Robotics Laboratory | Semester 1 | The program consists of a series of practical exercises plus coursework. Practical exercises will cover: - Robotics. - Automata . - Perception. - Various sensors. - Sensory feedback. |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950017 | Advanced Separation Processes | Semester 1 | Multicomponent distillation Adsorption and ion exchange systems Crystallization Membrane separation processes Non-conventional separation systems |
| 208 | Degree in Chemical Engineering | 2080053 | Chemical technology | Semester 1 | Raw materials for chemical processes. Energy sources. Organic and inorganic chemical technology. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040003 | Technological Project Management and Direction | Semester 2 | 1. Project development. 2. Project management and coordination. 3. Technical project management. 4. Financial project management. |
| 208 | Degree in Chemical Engineering | 2080004 | Physics I | Semester 1 | Mechanics, Oscillations and Waves. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970034 | Communications, Remote Control and Automation of Electrical Systems | Semester 1 | I. Basic communication concepts (modulation, multiplexing, transmission media, communication networks) II. Automation of the electrical transmission network III. Automation of distribution networks |
| 225 | Degree in Civil Engineering | 2250069 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| 199 | Degree in Telecommunications Technology Engineering | 1990031 | Design of Electronic Circuits and Systems | Semester 2 | Design of digital and analog circuits and systems. Filters. Analog-to-digital and digital-to-analog conversion. Electronic control systems |
| 199 | Degree in Telecommunications Technology Engineering | 1990026 | Multiservice Networks | Semester 1 | Block I: LAN Networks - Fundamentals of local area networks - Ethernet (802.3) - Ethernet switching - Virtual Local Area Networks - Advanced Aspects: QoS, basic security and management. Block II: WLAN Networks - Fundamentals of WLAN networks - Wifi (802.11): operation and performance analysis. - Advanced Aspects: QoS, basic security and management. Block III: Routing - Network Level: the routing problem - Intra-domain routing algorithms - Inter-domain routing algorithms. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210011 | Design and Planning of Industrial and Service Centers | Semester 2 | Basic principles of location Plant layout Transport and handling Regulations and accreditation |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210049 | Energy Technology | Semester 1 | 1) Heat transfer technology: Design and operation of heat exchangers 2) Thermal power generation: Operation of thermal power generators. Energy savings in thermal power generators 3) Fundamentals of cold production. Refrigeration systems by mechanical compression. Basic components of refrigeration installations. Analysis of refrigeration installations. 4) Energy savings and efficiency: context and regulatory framework, ISO 50001, 50006 and 52000-1, and decision-making procedure ------------------------------------------------------- 1) Heat transfer technology: Design and operation of heat exchangers 2) Thermal power generators: Operation of thermal power generators. Energy savings in thermal power generators 3) Fundamentals of cold production. Refrigeration system by mechanical compression. Basic components of refrigeration installations. Analysis of refrigeration facilities. 4) Energy saving and efficiency: context and regulatory framework, ISO 50001, 50006 and 52000-1, and decision-making procedure |
| 197 | Degree in Aerospace Engineering | 1970033 | Aeronautical Structures | Semester 2 | 1. Introduction to aircraft structures 1.1. Introduction to aircraft structures 1.2. Introduction to the design of aircraft structures 1.3. Introduction to structural design standards 1.4. Introduction to load determination 2. Analysis of thin-walled monocoque structures. Extension to complex and three-dimensional sections. 2.1. Review of elementary theory. Hypotheses. Notation. Simplifications. 2.2. Bending. 2.3. General relationships between stresses, strains and displacements. 2.4. Equilibrium equations. Twist and warping of sections. 2.5. Torsion in open, closed, single-cell and multi-cell tubes. 2.6. Shear in open tubes. Shear center. 2.7. Shear in closed, single-cell and multi-cell tubes. 2.8. Displacement calculation. Gyration. 3. Analysis of semi-monocoque structures. Extension to complex three-dimensional sections. 3.1. Structural idealization. Effective width of sheet metal panels. 3.2. Effect of idealization on the analysis of open and closed tubes. 3.3. Displacement calculation. 4. Structural instability analysis and application to idealized semi-monocoque structures . 4.1. Review of Euler and beam-column theory . 4.2. Instability of stringers . 4.3. Panel instability. 4.4. Stiffened panel problem. 5. Introduction to dynamic structural calculation. 5.1. The structure as a system of N degrees of freedom . 5.2. Equations and matrices of the straight bar . 5.3. Mass matrices. 5.4. Structural equations. 5.5. Solution to the problem . 5.6. Spectral loads . 6. Introduction to the design of aeronautical structures with composite material. 7. Calculation of joints in aeronautical structures 8. Fatigue and damage tolerance in aeronautical structures |
| 197 | Degree in Aerospace Engineering | 1970040 | Flight Mechanics and Flight Operations | Semester 2 | Aircraft Performance. Trajectories. Stability and Control. Flight Operations. |
| M164 | Master's Degree in Electrical Energy Systems | 51640008 | Numerical Methods for Electrical Systems | Semester 2 | - Storage and manipulation of sparse matrices. - Solution of linear systems. - Stability and ill-conditioning. High-dimensional systems. Optimal node ordering. - Linear optimization problems . - Nonlinear optimization problems . - Mixed integer optimization problems. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210017 | Materials Science | Semester 2 | 1. INTRODUCTION TO MATERIALS SCIENCE 2. ATOMIC SCALE OF MATERIALS: ORDER AND DISORDER 2.1 Intimate structure of materials 2.2 The atomic scale of metallic materials 2.3 The atomic scale of ceramic materials 2.4 The atomic scale of molecular materials 2.5 The atomic scale of polymeric materials 2.6 Crystalline imperfections 3. MICROSCOPIC SCALE OF MATERIALS: PHASE TRANSFORMATIONS AND MICROSTRUCTURE 3.1 Phase transformations 3.2 Phase diagrams in equilibrium 3.3 Non-equilibrium aspects 4. MACROSCOPIC SCALE OF MATERIALS: MACROSCOPIC PROPERTIES 4.1 Mechanical properties and behavior in service of materials 4.2 Electrical properties of materials 4.3 Thermal properties of materials 5. LABORATORY PRACTICES 5.1. Crystal structures (1.5 hours). 5.2. Metallographic preparation (1.5 hours) . 5.3. Basic metallography of steels (1.5 hours). 5.4. Metallography of non-ferrous metals (1.5 hours). 5.5. Hardness measurement (1.5 hours). |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560018 | Circuit theory | TO | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines. Circuit analysis techniques. |
| 203 | Degree in Industrial Technology Engineering | 2030170 | Integration of Renewable Energy | Semester 1 | Chapter I. Integration of renewable energies Chapter II. Photovoltaic energy Chapter III. Wind energy Chapter IV. Design of electrical installations for wind and photovoltaic farms Chapter V. Integration of renewable energy plants into the electrical grid |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210001 | Life Cycle Analysis (DIS) | Semester 1 | ISO 14000 Environmental Life Cycle Inventory Analysis Impact Assessment |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210023 | Data Engineering in Organization | Semester 1 | - Computer tools for data processing, management, and analysis. - Supervised machine learning. - Unsupervised machine learning. - Application to industrial organizations. |
| 225 | Degree in Civil Engineering | 2250030 | Metal structures i | Semester 2 | The subject is dedicated to the design and calculation of metal structures (ie structural steel). |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280019 | Control Fundamentals | Semester 2 | System modeling and identification. Time-response analysis. Stability analysis. Principles and techniques of system and process control. Design and implementation of basic control systems. Introduction to logic automation. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560046 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| M146 | Master's Degree in Industrial Engineering | 51460063 | Advanced Fluid Mechanics | Semester 2 | I. Review of the Navier-Stokes equations. II. Computational fluid dynamics (CFD) III. Application of CFD to engineering flows REFERENCES A. BARRERO and M. PEREZ-SABORID, Introduction to Fluid Mechanics and its Applications, Ed. McGraw-Hill, 2005. F. M. WHITE, Fluid Mechanics, Ed. McGraw-Hill, 2004. G. K. BATCHELOR, An Introduction to Fluid Dynamics, Ed. Cambridge University Press, 1967. LANDAU and LIFSHITZ, Fluid Mechanics, Pergamon Press. SCHLICHTING, Boundary Layer Theory, Ed. McGraw-Hill. (There is a Spanish version 'Boundary Layer Theory' in the ETSI Library) |
| 197 | Degree in Aerospace Engineering | 1970038 | Machine Mechanics and Vibrations | Semester 2 | Kinematic schematization of machines and mechanisms. Introduction to machine kinematics and dynamics. Machine elements. Mechanical vibrations. |
| 197 | Degree in Aerospace Engineering | 1970067 | Airport Construction III | Semester 2 | Construction materials. Design and construction of airport building elements. Building regulations. Airport building typology and solutions. The thematic sections taught are: PART I: ON-GROUND WORKS; PART II: AIRPORT PAVEMENTS; PART III: DESIGN AND CONSTRUCTION OF AIRPORT BUILDING ELEMENTS |
| 199 | Degree in Telecommunications Technology Engineering | 1990068 | Artificial vision | Semester 1 | Descriptors: Processing and segmentation techniques. Pattern recognition. Motion detection. |
| 199 | Degree in Telecommunications Technology Engineering | 1990062 | Advanced Telematic Services | Semester 1 | Domain Name Service, Centralized Directories, Email and Secure Shell |
| 199 | Degree in Telecommunications Technology Engineering | 1990090 | Robotics | Semester 2 | Analysis of existing methodologies for robot control. Design, documentation, and commissioning of a robotic system. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900033 | Hydrological Planning | Semester 1 | THEMATIC BLOCK 1: INTRODUCTION Topic 1 - Introduction. Water resources and the hydrological cycle. Types of water resources. Water resource assessment. Water balance of a territory. Introduction to Water Resources Planning. History of planning in Spain. Need for planning. Objectives of water resources planning. THEMATIC BLOCK 2: LEGAL AND INSTITUTIONAL FRAMEWORK Topic 2 - Legal Framework. Directive 2000/60/EC, the Water Framework, and its objectives. The Spanish Constitution and water powers. Hydrological planning in the Water Law and in the Regulations and Instructions on hydrological planning. Topic 3 - Institutional framework. Public Water Administration. Hydrographic Demarcations in Spain. Organization and operation. Topic 4 - Hydrological Demarcation Plans and the National Hydrological Plan. Legislation. Concept. Content of Hydrological Plans. Procedure for the preparation and approval of River Basin Hydrological Plans. The National Hydrological Plan. Current status of Planning for the Demarcations in Andalusia. THEMATIC BLOCK 3: TOOLS Topic 5 - Geographic information systems applied to water resources management. Introduction. Geographic information systems, GIS. Concept. Tools and functions. Digital terrain models. Current Water Information Systems. Information repositories. Practical application. Topic 6 - Modeling for water resources planning and management. Model concept. Decision-making support systems. AQUATOOL. Practical application. THEMATIC BLOCK 4: WATER RESOURCE EXPLOITATION SYSTEMS. Topic 7 - The hydrological basin as a water management unit. Definition and characterization of hydrological basins. Data processing for hydrological computer modeling: climatic, rainfall, meteorological, soil type, and other information. Practical application. Topic 8 - Contributions. Methodology for estimating contributions. Using observed data, extension and transposition of contribution series. Application of continuous hydrological models: Evalhid. Practical application. Topic 9 - Infrastructure of a Hydraulic Resources System. Dams. Pipelines. Desalination plants. Reservoirs. Topic 10 - Water uses, demands, and environmental requirements. Introduction. Legislation. Allocation and returns. Uses and concessions. Urban supply and methodology for evaluating demands. Industrial supply. Agricultural uses and methodology for evaluating demands. Energy uses. Aquaculture. Environmental protection and its relationship with water resources planning. Ecological flows. Allocations and reserves. Practical application. Topic 11 - Supply guarantee. Guarantee criteria. Indices and methods for quantifying the degree of demand satisfaction. Guarantee curves. Effect of climate change. Practical application. Topic 12- Various technical solutions to resource shortages. Interbasin transfers. Desalination plants. Underground resources. Practical application. THEMATIC BLOCK 5: SYSTEMS EXPLOITATION OF WATER RESOURCES IN EXTREME SITUATIONS Topic 13- Extreme situations: Droughts. Concept. Characterization. Types of droughts. Impacts. Indicators: SPI, Palmer, State Index. Drought mitigation measures: savings, generation of additional resources, reduction of demands. Planning for droughts. Related regulations. Action plans in alert and possible drought situations (PES). Topic 14- Extreme situations: Floods. Concept. Characterization. Impact of floods, historical overview. Regulations related to planning in flood-prone areas, DPH, etc. Hydrological and hydraulic analysis of floods. Structural measures. Non-structural measures: floodplain planning, channel monitoring and control. Telemetry systems. Automatic hydrological information systems (AHIS). |
| M190 | Master's Degree in Civil Engineering (2019) | 51900027 | Urban Planning and Territorial Planning | Semester 2 | Course Content. GENERAL INFORMATION. The content will be taught in two approaches that will coexist throughout the coursework. Both are complementary in their approach to the knowledge they provide. Thus, each topic will present two converging lines of work: Those labeled "theoretical basis" refer to topics necessary for a basic understanding of the discipline, without which it is impossible to address, integrate, and contextualize the practical aspects. Their purpose is to provide tools for understanding the city and its territory by projecting its planning onto its most important constituent factors (physical environment, urban morphology, activities, mobility, etc.) in the current context. Those labeled "applied knowledge" address the description of the urban planner's work through detailed planning, the scale of which is closest to the constructive materialization that urbanization represents. BLOCK 1. THE URBAN AND ITS PLANNING RESOURCES IN THE CURRENT CONTEXT. Topic 1. Theoretical Basis: The urban environment and its current dynamics as an area of challenge for urban and territorial planning and engineering. Applied knowledge: Tools for analyzing urban and territorial space for intervention. Topic 2. Theoretical Basis: Urban Planning and Territorial Planning: historical context and definition of both disciplines. Applied knowledge: Territorial plans as a framework for urban planning and sectoral planning. Topic 3. Theoretical Basis: Urban Planning and Territorial Planning legislation: regulation of comprehensive planning. Applied knowledge: Land classification, urban structure and zoning, planning and management units. Topic 4. Theoretical Basis: Levels of action in the city through urban planning: the planning hierarchy. Applied knowledge: General and detailed planning: scales and levels of definition. BLOCK 2: BASIC FEATURES OF URBAN DEVELOPMENT PLANNING. Topic 5. Theoretical Basis: The redesign of existing cities and the creation of new cities as aspects of urban planning. Applied Knowledge: Definition of an area of intervention: nature of the intervention, legal framework, insertion into the urban structure, determination of pre-existing conditions, and historical research as a means of framing the intervention within the environment. Topic 6. Theoretical Basis: The legal dimension of urban action; modification of land ownership. Information. Applied Knowledge: Public and private sectors and their characterization and implementation in urban planning. Topic 7. Theoretical Basis: The social infrastructure of the city: facilities in the context of planning. Applied Knowledge: Criteria for determining the surface area and characteristics of facility reserves. Topic 8. Theoretical Basis: The definition of open space as a basic element of the city project. Applied Knowledge: Location, design criteria, and integration of open space into urban planning. Topic 9. Theoretical Basis: The requirements of mobility in the configuration of urban space. Applied knowledge: Conditions for the definition and design of the road network. Topic 10. Theoretical basis: The diversity of the urban fabric and its treatment in planning. Applied knowledge: The delimitation of urban planning zones. Topic 11. Theoretical basis: The landscape as a resource in urban planning. Applied knowledge: Visual integration of urban interventions in the city and territory. Topic 12. Theoretical basis: Sustainable urban planning as an integrating framework for actions on the city. Applied knowledge: Integration of sustainability variables into urban design. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900012 | Railways | Semester 2 | GENERALITIES. Topic 1. Introduction to railways. THEMATIC BLOCK I: INFRASTRUCTURE TECHNOLOGY. Topic 2. Rails. Topic 3. Track parameters. Topic 4. Sleepers. Topic 5. Fastenings. Topic 6. Ballast. Topic 7. Slab track. Topic 8. Platform. Topic 9. Origin and evaluation of stresses. Topic 10. Mechanical behavior of the track. Topic 11. Dimensioning of the track and its elements. Topic 12. Beams and special tracks. Topic 13. Special equipment. Topic 14. Electrification. THEMATIC BLOCK II: RAILWAY DYNAMICS. Topic 15. Dynamics of mechanical systems. Deterministic stresses. Topic 16. Dynamics of mechanical systems. Stochastic stresses. Topic 17. Track irregularities. Topic 18. Wheel-rail contact. Topic 19. Rolling stock modeling. Topic 20. Global dynamics of railway vehicles. Topic 21. Vehicle-track interaction. THEMATIC BLOCK III: ROLLING STOCK TECHNOLOGY. Topic 22. Basic elements of rolling stock. Topic 23. Structure. Topic 24. Resistance, stresses and traction. Topic 25. Braking. Topic 26. Traction and collision devices. Topic 27. Special technologies. Topic 28. Metropolitan railways. Topic 29. Automated transport. THEMATIC BLOCK IV: HIGH-SPEED TECHNOLOGY. Topic 30. Infrastructure. Topic 31. Motive material. Topic 32. Structure. Topic 33. Magnetic levitation trains. Topic 34. Other technologies. BASIC BIBLIOGRAPHY GARG, VK DYNAMICS OF RAILWAY VEHICLE SYSTEMS .Canada: Academic Press (1984). OLIVEROS, F.; LOPEZ PITA, A.; MEGIA PUENTE, MJ RAILWAY TREATY I. VIA. Madrid: Rueda (1977). HAY, WW RAILROAD ENGINEERING .USA : John Wiley & Sons (1982). NEWLAND, FROM RANDOM VIBRATIONS AND SPECTRAL ANALYSIS. USA: Longman (1984). ANDREWS, HI RAILWAY TRACTION. THE PRINCIPLES OF MECHANICAL AND ELECTRI¬CAL RAILWAY TRACTION.Netherlands: Elsevier Science Publishers (1986). PAZ, M. STRUCTURAL DYNAMICS. THEORY AND COMPUTATION. USA: Van Nostrand Reinhold Co. (1980). |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920048 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 199 | Degree in Telecommunications Technology Engineering | 1990049 | High Frequency Circuits | Semester 1 | Description of networks and circuits in S-parameters . Impedance matching. Resonators. Couplers, hybrids, and power dividers. Microwave filters. Solid-state microwave devices. Microwave amplifiers. Microwave signal generators. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930035 | Circular Economy and Sustainability | Semester 1 | Course Program Topic 1. Concepts of Sustainability and Circular Economy Topic 2. Sustainability and Environmental Management PRACTICAL CASE No. 1: Technical bases for the implementation of an integrated urban sustainable development process: the Local Agenda 21. Sustainability diagnosis, indicator system and action plan. Topic 3. Environmental Management Systems Topic 4. Economy and Environment PRACTICAL CASE No. 2: Strategy for plastics in a circular economy Topic 5. Circular Economy and Solid Waste PRACTICAL CASE No. 3: Advanced Landfill Mining (Enhanced Landfill Mining). STUDENT SEMINAR No. 1 Topic 6. Ecodesign and Ecolabel Topic 7. Quantification of Sustainability STUDENT SEMINAR No. 2 PRACTICAL CASE No. 4: The circular economy in the fertilizer production. European Commission Regulations CASE STUDY NO. 5: Critical Raw Materials and the Circular Economy (EU) CASE STUDY NO. 6: Implementation of the Deposit, Return and Refund System (DRRS) in the city of Seville/Andalusia/Spain. Combined example of circular economy and sustainability. STUDENT SEMINAR NO. 3 STUDENT SEMINAR NO. 4 STUDENT SEMINAR NO. 5 STUDENT SEMINAR NO. 6 NOTE: Throughout the course, an additional lecture given by a guest lecturer may be offered. |
| 203 | Degree in Industrial Technology Engineering | 2030125 | Railways | Semester 2 | GENERALITIES. Topic 1. Introduction to railways. THEMATIC BLOCK I: INFRASTRUCTURE TECHNOLOGY. Topic 2. Rails. Topic 3. Track parameters. Topic 4. Sleepers. Topic 5. Fastenings. Topic 6. Ballast. Topic 7. Slab track. Topic 8. Platform. Topic 9. Origin and evaluation of stresses. Topic 10. Mechanical behavior of the track. Topic 11. Dimensioning of the track and its elements. Topic 12. Beams and special tracks. Topic 13. Special equipment. Topic 14. Electrification. THEMATIC BLOCK II: RAILWAY DYNAMICS. Topic 15. Dynamics of mechanical systems. Deterministic stresses. Topic 16. Dynamics of mechanical systems. Stochastic stresses. Topic 17. Track irregularities. Topic 18. Wheel-rail contact. Topic 19. Rolling stock modeling. Topic 20. Global dynamics of railway vehicles. Topic 21. Vehicle-track interaction. THEMATIC BLOCK III: ROLLING STOCK TECHNOLOGY. Topic 22. Basic elements of rolling stock. Topic 23. Structure. Topic 24. Resistance, stresses and traction. Topic 25. Braking. Topic 26. Traction and collision devices. Topic 27. Special technologies. Topic 28. Metropolitan railways. Topic 29. Automated transport. THEMATIC BLOCK IV: HIGH-SPEED TECHNOLOGY. Topic 30. Infrastructure. Topic 31. Motive material. Topic 32. Structure. Topic 33. Magnetic levitation trains. Topic 34. Other technologies. BASIC BIBLIOGRAPHY GARG, VK DYNAMICS OF RAILWAY VEHICLE SYSTEMS .Canada: Academic Press (1984). OLIVEROS, F.; LOPEZ PITA, A.; MEGIA PUENTE, MJ RAILWAY TREATY I. VIA. Madrid: Rueda (1977). HAY, WW RAILROAD ENGINEERING .USA : John Wiley & Sons (1982). NEWLAND, FROM RANDOM VIBRATIONS AND SPECTRAL ANALYSIS. USA: Longman (1984). ANDREWS, HI RAILWAY TRACTION. THE PRINCIPLES OF MECHANICAL AND ELECTRI¬CAL RAILWAY TRACTION.Netherlands: Elsevier Science Publishers (1986). PAZ, M. STRUCTURAL DYNAMICS. THEORY AND COMPUTATION. USA: Van Nostrand Reinhold Co. (1980). |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210098 | Industrial Security (DIS) | Semester 1 | Legislation. Risk identification techniques. Consequence analysis. Quantitative risk analysis. Risk reduction. Emergency plans. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210091 | Integrated Industrial Plant Project | Semester 1 | Design of industrial buildings and auxiliary facilities. Facility projects. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210030 | Renewable energy | Semester 2 | 1. Renewable energy resources; renewable energy in the energy context 2. Photovoltaic solar energy 3. Concentrated solar thermal energy 4. Solar hot water production 5. Passive solar systems in buildings 6. Wind energy 7. Biomass 8. Other renewable energies |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210010 | Machine Design and Calculation (IMF) | Semester 2 | Analysis and design of machine elements. Machine installations. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210018 | Fluid mechanics | Semester 2 | Basic principles and general differential (Navier-Stokes) and integral equations of fluid mechanics. Dimensional analysis. Fluid statics. Incompressible viscous flows. Ideal flows in ducts. Fundamentals of boundary layers and turbulence. Turbulent flow in ducts, incompressible and compressible. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970036 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 197 | Degree in Aerospace Engineering | 1970005 | Mathematics I | Semester 1 | Linear Algebra and Geometry: Conics and Quadrics. Complex Numbers and Polynomial Factorization. Matrices, Determinants, and Systems of Linear Equations. Vector Spaces and Linear Transformations. Eigenvalues and Eigenvectors, Diagonalization of Matrices. Orthogonality and Best Approximation. Real Symmetric Matrices and Quadratic Forms. |
| M228 | Master's Degree in Operation of Space Systems | 52280009 | Space Communications | Semester 2 | Satellite communications systems Ground stations Radio link Modulation Multiplexing and multiple access Satellite networks GNSS |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280076 | Computer Aided Design | Semester 1 | THEMATIC BLOCK I: GENERATION OF SOLIDS. THEMATIC BLOCK II: PRODUCTION OF DRAWINGS. THEMATIC BLOCK III: MODELING OF SHEET METAL PARTS. THEMATIC BLOCK IV: ASSEMBLY DESIGN. THEMATIC BLOCK IV: GENERATION OF LINES AND SURFACES. |
| 208 | Degree in Chemical Engineering | 2080051 | Manufacturing technology | Semester 2 | 1. Introduction to manufacturing 2. Measurement, verification and quality control techniques 3. Metal casting processes 4. Plastic forming of metals 5. Machining processes 6. Polymeric and composite materials 7. Joining processes 8. Manufacturing and production systems 9. Non-conventional manufacturing processes 10. Introduction to additive manufacturing |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210062 | Hydrogen-Based Systems | Semester 2 | BLOCK 1. Introduction to hydrogen technology. Hydrogen as a future energy source. BLOCK 2. Hydrogen production. BLOCK 3. Hydrogen storage. BLOCK 4. Safety in hydrogen technology. BLOCK 5. Fuel cells. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210023 | Hydraulic Installations and Machinery | Semester 1 | Hydraulic installations. Calculation of piping and fitting systems. Hydraulic turbomachinery. Characteristic curves. Auxiliary elements. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040005 | Digital Electronics for Communications | Semester 1 | Block 1: Communications Systems Block 2: HDL Design Block 3: Verification of Digital Circuits |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040011 | Next Generation Networks | Semester 2 | Software-defined networks. Network functions virtualization. Functional architecture of 5G networks. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210025 | Structural Integrity of Mechanical Systems (IMF) | Semester 1 | Fundamentals and criteria for machine design. Machine failure modes. Fatigue and fracture design. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210003 | Advanced Automation (AR) | Semester 2 | Monitoring systems. Advanced automation technologies. Real-time computing systems. Industrial local networks. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210134 | Optimization and Control in Energy Systems | Semester 2 | Common thermal processes. Dynamic analysis. Process controllability. Optimization and control. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270006 | Company | Semester 2 | Adequate understanding of the concept of business, the institutional and legal framework of business, and business organization and management. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280065 | Optoelectronics | Semester 2 | |
| M143 | Master's Degree in Aeronautical Engineering | 51430008 | Numerical methods | Semester 1 | Knowledge of advanced aspects of mathematical analysis and its applications to industrial engineering. Differential equations and systems of equations. Partial differential equations. Examples from engineering. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560033 | Computer Aided Design and Manufacturing | Semester 2 | Computer-aided design (CAD) of mechanical elements. Solid, surface, and assembly modeling procedures. Generation of engineering project drawings. Computer-aided manufacturing (CAM). Virtual manufacturing. |
| M143 | Master's Degree in Aeronautical Engineering | 51430028 | helicopters | Semester 2 | Rotor aerodynamics. Performance. Blade dynamics. Conceptual design. |
| 197 | Degree in Aerospace Engineering | 1970035 | Air Navigation Fundamentals | Semester 2 | - Cartography and Geodesy. - Navigation Methods. - Navigation Charts. - Navigation Instruments. |
| M146 | Master's Degree in Industrial Engineering | 51460105 | Transients in Electrical Machines and Drives | Semester 2 | 1. ELECTROMECHANICAL ENERGY CONVERSION 2. TRANSFORMATIONS OF VARIABLES 3. INDUCTION MACHINES 4. SYNCHRONOUS MACHINES 5. LINEARIZATION AND REDUCED MODELS OF AC MACHINES 6. ELECTRICAL DRIVES 7. CONTROL TECHNIQUES |
| 197 | Degree in Aerospace Engineering | 1970064 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| 197 | Degree in Aerospace Engineering | 1970024 | Structures | Semester 1 | Prior knowledge and skills: The following knowledge is considered essential for following the subject: Calculus Algebra Rational Mechanics Strength of Materials Thematic blocks Calculation of stresses in bars Introduction to structural analysis Plane lattice systems of articulated structures. General structural calculation methods. Introduction to FEM. |
| M181 | Master's Degree in Chemical Engineering | 51810007 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 197 | Degree in Aerospace Engineering | 1970063 | Unmanned Aerial Vehicles | Semester 2 | Components of an unmanned aerial system. Platform types and classifications. Navigation, guidance, and control of unmanned aircraft. Techniques and technologies for collision perception and avoidance. Autonomous landing. Trajectory planning. Ground stations. Applications. Airspace integration. Regulations. |
| 199 | Degree in Telecommunications Technology Engineering | 1990015 | Signals and Systems | Semester 1 | Fundamentals of continuous and discrete-time signals. Linear systems. Fourier transform. Signal sampling and reconstruction. Z transform. Filtering concepts. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900016 | Methodology and History of Civil Engineering | Semester 1 | ¿ Conceptions of science, technology, engineering, and society ¿ Specific aspects of civil engineering and public works ¿ Popular technology and architecture: a form of pre-civil engineering ¿ Review of some chapters in the history of civil engineering. Ancient empires, Rome and the Hellenistic world, the Middle Ages, the Renaissance , the Enlightenment, and the Industrial Revolution ¿ Overview of civil engineering teaching. ¿ Gallery: some prominent civil engineers and their works. ¿ Proposal for end-of-course projects. |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950016 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960033 | Advanced Supply Chain Design and Management | Semester 2 | Advanced models for supply chain design and management Coordination in supply networks |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960040 | Business Management Tools | Semester 2 | 1. Financial analysis and management. 2. Commercial management. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210084 | Computational Methods, Monitoring and Control of Structures (DECI) | Semester 1 | Sensors and instrumentation systems for monitoring industrial structures. Mechanical testing for the static and dynamic characterization of structures. Numerical simulation: transient behavior, nonlinear analysis. Calibration of numerical models. Active and passive structural control systems. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210014 | Circuit theory | Semester 1 | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560058 | Power Production Systems | Semester 2 | Power plants: steam turbines, gas turbines, reciprocating engines, and combined cycles. Plant specifics depending on the heat source used. Regulation. Emissions |
| M143 | Master's Degree in Aeronautical Engineering | 51430007 | Advanced Flight Mechanics | Semester 1 | Estimation of stability derivatives. Advanced stability and control studies. Flight qualities. Nonlinear dynamics. Gust response. |
| 199 | Degree in Telecommunications Technology Engineering | 1990023 | Power Electronics | Semester 1 | Energy sources, especially solar photovoltaic and thermal. Electrical engineering and power electronics. Power supplies for telecommunications equipment. Applications in telecommunications infrastructure. |
| 208 | Degree in Chemical Engineering | 2080061 | Fluid Mechanical Engineering | Semester 1 | Fluid dynamics around solid bodies. Introduction to hydraulic systems. Characterization of hydraulic machines. Pressure, level, and flow measurement in hydraulic systems. Calculation of hydraulic and pneumatic systems. Compressibility effects in pipeline networks. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990010 | Waste Engineering | Semester 1 | Domestic waste: collection and management. Characterization and treatment of hazardous waste. Biological treatments. Thermal treatment. Waste landfill. Radioactive waste. Soil reclamation. Topic 1. Introduction. Waste. General problems. Topic 2. Legislation. Characterization of domestic and commercial waste. Management and characterization of hazardous waste. Topic 3. Urban waste management and collection systems. Recycling. Topic 4. Urban waste processing and separation technologies . Topic 5. Biological waste treatment. Composting. Anaerobic digestion. Topic 6. Thermal treatment of waste. Topic 7. Physicochemical treatment of hazardous waste. Topic 8. Stabilization-solidification treatments of hazardous waste. Topic 9. Waste landfill. Topic 10. Radioactive waste management. Topic 11. Consumer goods waste management. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600014 | Advanced Digital Systems and Applications | Semester 1 | Thematic blocks: Embedded systems and IoT systems Embedded operating systems Programmable devices Laboratory practices on embedded systems and programmable devices. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210004 | Power Plants (EL) | Semester 2 | Electricity generation from fossil fuels and nuclear power plants Hydroelectric power plants Pumped storage power plants Conventional power plants Power-frequency control Synchronous generator voltage control |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830010 | Air Pollution Engineering | Semester 1 | Analysis of industrial emissions. Definition of BACT. Applications of abatement techniques. Cross-media effects. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320011 | Composite material mechanics | Semester 2 | Thematic blocks: Morphology and manufacturing. Behavior of a sheet. General theory of laminates. Beams and plates. Joints. Acceptance and requalification tests. Covered topics: 1. Introduction to composite materials. 2. Law of behavior of a sheet. 3. Mechanical behavior of a sheet. 4. Mechanical behavior of a laminate. 5. Analysis of structural elements of composite material. 6. Joints in composite materials. 7. Acceptance and requalification tests. Practical sessions: 1. Manufacturing of a laminate. 2. Preparation of test specimens. 3. Characterization tests. 4. Acceptance and requalification tests. 5. Determination of the strength of a laminate. 6. Finite element modeling. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990007 | Quality management | Semester 1 | Basic quality concepts. Regulations on the verification and control of facilities, products, and services. Global regulatory system. Quality management models and systems. ISO 9000, 14000, and 45000 families Audits, certifications, testing, and reports. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210058 | Gas Turbine and Combined Cycles | Semester 1 | I. GAS TURBINES: 1. SIMPLE CYCLE. 2. REGENERATIVE SIMPLE CYCLE. 3. COMPOUND CYCLE. 4. EFFECT OF BLADE COOLING ON PERFORMANCE. 5. OFF-DESIGN OPERATION. 6. TECHNOLOGICAL DEVELOPMENT OF GAS TURBINES. II. COMBINED CYCLES: 1. THERMODYNAMIC FUNDAMENTALS OF COMBINED CYCLES. 2. EXHAUST GAS ENERGY RECOVERY. 3. CYCLES WITH STEAM PRODUCTION AT ONE PRESSURE. 4. CYCLES WITH STEAM PRODUCTION AT VARIOUS PRESSURES. 5. CYCLES WITH INTERMEDIATE SUPERHEATING. III. EMISSIONS. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040018 | Communications and Data Analysis in IoT | Semester 1 | Block I. Short-range wireless interfaces for IoT. Block II. Long-range wireless interfaces for IoT. Block III. Data analysis and artificial intelligence in IoT. --------------------- English Version --------------------- CONTENTS OR THEMATIC BLOCKS Block I. Short-range wireless interfaces for IoT. Block II. Long-range wireless interfaces for IoT. Block III. Data analysis and artificial intelligence in IoT. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210027 | Machines, Drives and Electric Mobility (EL) | Semester 1 | The contents included in the Verification Report of the Title are the following: Analysis, design, testing, selection and applications of electrical machines Control of electrical machines, variable speed drives and applications Electric vehicles: Motor equipment, torque-speed relationship, traction and braking, energy accumulators, efficiency and energy management The contents of the subject are organized in the following thematic blocks: 1. Introduction to electrical machines and drives 2. Energy and economic efficiency of electrical drives 3. Variation of the speed of asynchronous or induction motors 4. Introduction to vector or oriented field control 5. Application of drives in electric mobility 6. Storage and mechanical system in electric mobility 7. Integration of electrical drives and mechanical systems |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270004 | Mathematics II | Semester 1 | 1) Thematic blocks Block 1. Functions and derivatives. Block 2. Integration. Block 3. Taylor polynomials and series. Block 4. Ordinary differential equations. 2) Topics 1. Functions and derivatives. 1.1. Continuity and differentiability of functions. 1.2. Applications of derivatives: extremes of functions and solution of nonlinear equations, Newton's method. 1.3. Representation of curves. 2. Integration. 2.1. Calculus of primitives. 2.2. Definite integral. 2.3. Numerical integration. 2.4. Improper integrals. 2.5. Geometric applications. 3. Taylor polynomials and series. 3.1. Taylor polynomials. 3.2. Numerical series. 3.3. Power series. 3.4. Fourier series. 4. Ordinary differential equations. 4.1. Introduction to differential equations and systems of equations. 4.2. First-order differential equations. 4.3. Higher-order differential equations. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560040 | Data Engineering | Semester 1 | Computer tools for data processing, management, and analysis. Supervised machine learning. Unsupervised machine learning. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280014 | Material resistance | Semester 1 | Introduction to Elasticity. Basic concepts. Tension and bending in solid and thin-walled sections. Stress diagram, displacement calculation. Analysis of bar structures. Instability. Torsion. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560044 | Computational Mathematics | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| M146 | Master's Degree in Industrial Engineering | 51460072 | Modeling and Optimization of Management Problems | Semester 2 | Subject descriptors: - Operations research. - Artificial intelligence applied to industrial management problems. - Optimization in Project Management. Thematic blocks: BLOCK 1: Modeling management problems. BLOCK 2: Optimization of management problems and project management. BLOCK 3: Artificial intelligence applied to industrial management problems. BLOCK 4: Project development and management. Coding of models and resolution methods. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550008 | Fundamentals and Simulation of Manufacturing Processes | Semester 2 | - Fundamentals of Forming Process Analysis: Plastic Forming; Machining; Non-Conventional Processes. - Design for Manufacturing and Assembly (DFMA). - Manufacturing Process Simulation. |
| 197 | Degree in Aerospace Engineering | 1970019 | Fluid Mechanics I | Semester 2 | General equations and principles. Dimensional analysis. Motions at low and high Reynolds numbers. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600015 | Electronic Systems for Aerospace Applications | Semester 2 | It has four thematic blocks: Block I. Testing and qualification of electronic components Block II. Testing and qualification of complex electronic systems Block III. Design for qualification of programmable electronic devices for aeronautics and space Block IV. Design of aerospace systems |
| 197 | Degree in Aerospace Engineering | 1970012 | Mathematics expansion | Semester 1 | Knowledge of advanced aspects of Mathematical Analysis and its applications: Differential equations. Laplace transform. Systems of differential equations. Fourier series. Partial differential equations. Conformal transformations. |
| 197 | Degree in Aerospace Engineering | 1970004 | Physics I | Semester 1 | Mechanics. Oscillations. Waves. |
| 197 | Degree in Aerospace Engineering | 1970043 | Radio Frequency Signals and Systems | Semester 1 | - Analog and digital signals and systems. - Noise. - Digital signal processing. - Radio frequency systems. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900020 | Maritime works | Semester 1 | Typology of maritime works Exterior works Shelter works Access works Interior works Docking works |
| 203 | Degree in Industrial Technology Engineering | 2030071 | Expansion of Kinematics and Dynamics of Machines | Semester 1 | UNIT I ANALYSIS IN THE FREQUENCY DOMAIN 1. Introduction. Fourier series expansion; Fourier transform 2. Discrete-time periodic signals 3. Typical errors. Alising, Leakage 4. Discrete-time Fourier transform 5. The fast Fourier transform (FFT) 6. Numerical calculation of the frequency response of a system. Wraparound error UNIT II VIBRATIONS OF SYSTEMS WITH VARIOUS DEGREES OF FREEDOM 1. Introduction 2. Formulation of the system 3. Definition of system properties 4. Change of coordinates 5. Free undamped vibrations. Calculation of frequencies and modes. 6. Free vibrations with damping 7. General response of a system 8. Numerical methods for calculating the response. Step-by-step integration methods TOPIC III METHODS FOR CALCULATING NATURAL FREQUENCIES AND VIBRATION MODES 1. Introduction 2. Inverse iteration method 3. Holzer method 4. Rayleigh method 5. Transfer matrix method TOPIC IV VIBRATIONS OF CO-CONTINUOUS SYSTEMS 1. Introduction 2. Torsional vibrations 3. Longitudinal vibrations of beams 4. Transverse vibrations of beams 5. Modal analysis of the response TOPIC V DISCRETE MODELS OF CO-CONTINUOUS SYSTEMS 1. Introduction 2. Discretization by mass concentration 3. The Rayleigh-Ritz method 4. A particular case. The finite element method TOPIC VI EXPERIMENTAL MODAL ANALYSIS 1. Introduction 2. Theoretical foundations of Experimental Modal Analysis in 1 DOF systems 3. Experimental Modal Analysis in N DOF systems 4. Practical realization of an experimental modal analysis TOPIC VII NONLINEAR VIBRATIONS 1. Introduction 2. Graphical methods. Phase plane 3. Analytical methods 4. Forced vibrations 5. Numerical methods TOPIC VIII RANDOM VIBRATIONS 1. Introduction 2. Basic concepts 3. Random process 4. Autocorrelation of stationary processes 5. Spectral density of stationary processes 6. Relationship between autocorrelation and spectral density 7. Cross-correlation and spectral density of stationary processes 8. Autocorrelation and spectral density of derived processes 9. Superposition of stationary processes 10. Broadband and narrowband processes 11. Response of one-degree-of-freedom systems 12. Response of multi-degree-of-freedom systems 13. Response statistics TOPIC IX VIBRATIONS IN ROTATING MACHINES 1. Introduction 2. Jeffcot model 3. Response of the system without damping 4. Response of the system with external damping 5. Response of the system with internal and external damping 6. Critical speeds TOPIC X DIAGNOSIS BY VIBRATION MEASUREMENT 1. Introduction 2. Description of some types of machine defects. 3. Spectrum modification caused by different types of faults. 4. Fault identification by vibration measurement. 5. Examples. |
| 208 | Degree in Chemical Engineering | 2080001 | Graphic expression | TO | Block I. Introduction Block II. Dihedral System Block III. System of Dimensioned Plans Block IV. Axonometric System Block V. Basic Standardization of Technical Drawings |
| 203 | Degree in Industrial Technology Engineering | 2030127 | Electrical Energy Management | Semester 2 | Energy audits. Electricity rates. Energy efficiency in transformers. Energy efficiency in motors. Energy efficiency in variable speed drives. Economic section of facilities. Instrumentation for energy audits. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970043 | Active Distribution Networks and Demand Management | Semester 1 | Block I Generalities and Characteristics of Distribution Networks Lesson 1: Introduction and generalities Lesson 2: Components and characteristics of distribution networks Lesson 3: Microgrids Block II Modeling and Analysis of Distribution Networks Lesson 4: Electrical modeling of lines and loads Lesson 5: Electrical modeling of transformers Lesson 6: Load flows in distribution networks Block III Optimization of Medium Voltage Networks Lesson 7: Characteristics of improvement in the operation of MV networks Lesson 8: Voltage and reactive control in Medium Voltage networks Lesson 9: Network reconfiguration Block IV Optimization of Low Voltage Networks Lesson 10: Characteristics of improvement in the operation of LV networks Lesson 11: Control in Low Voltage networks Block V Demand Management Lesson 12: Demand Management |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270008 | Graphic expression | Semester 2 | Block 1 Topic 1: Representation theory. 1.1- Projections. Definition and properties. Classification. 1.1.1.- Conic. 1.1.2.- Cylindrical, oblique, and orthogonal. 1.1.3.- Invariants. Topic 2: Standardization of Technical Drawings. 2.1.- Types of Technical Drawings. 2.2.- General information on UNE and ISO Standards. 2.3.- Rules for the formation of series of formats. 2.4.- Formal and functional aspects of plan presentation: margins, boxes, signals, and boxes. Numbering, scales, and dimensions. 2.5.- Standardized and customized boxes. 2.6.- Labeling. 2.7.- Line groups. Topic 3: Views and Sections. 3.1.- Main views. European and American systems. 3.2.- Necessary and sufficient views. 3.3.- Particular views. 3.4.- Interrupted views. Simplification of symmetrical parts. 3.5.- Sections and cuts: differentiation. 3.6.- Total and partial cuts. Cuts along parallel and oblique planes. Bent sections. 3.7.- Hatching of cut surfaces. 3.8.- Assembly drawings. Parts lists. Block 2 Topic 4: Dimensioning. 4.1.- Purpose of dimensioning. 4.2.- General principles. 4.3.- Material execution of dimensioning. 4.4.- Arrangement of dimensions: in series, in parallel and combined. Dimensioning by coordinates. 4.5.- Dimensioning of repetitive and equidistant elements. 4.6.- Dimensioning of cylindrical, conical and spherical bodies. Conicity and inclination. 4.7.- Dimensioning of chamfers, roundings, and countersinks. Topic 5: Dimensioning with tolerances. Transfer of dimensions. 5.1.- Dimensioning with tolerances. 5.2.- Definitions. Tolerance. Indication on technical drawings. 5.3.- Problems of dimensioning tolerances. Incompatibility of related dimensions. 5.4.- Transfer of dimensions. Topic 6: Standardization of tolerances and fits. 6.1.- Standardization of tolerances. 6.1.1.- Definitions. 6.1.2.- Quality and position of the tolerance zone. 6.2.- Fits. 6.2.1.- Definitions. Inscription on technical drawings. 6.2.2.- ISO fit systems. 6.2.3.- Considerations for determining limit clearances. 6.3.- Determining a standardized fit. Topic 7: Functional dimensioning. 7.1.- Introduction: The need to define functional dimensions. 7.2.- Definition of functional dimensioning. 7.3.- Study of the operating conditions of some devices. Topic 8: Surface states. Geometric tolerances. 8.1.- Classification, measurement, and assessment of surface irregularities. 8.2.- Indications on technical drawings of surface roughness and other special state characteristics. 8.3.- Introduction to geometric tolerances. Their necessity. 8.4.- Classification. Basic symbols. 8.5.- Inscription on technical drawings. 8.6.- Interpretation of geometric tolerances. Examples. Block 3 Topic 9: Removable joint systems. 9.1.- Introduction to the study of threaded elements: definition and basic geometric characteristics of threads. 9.2.- Fixing and transmission threads. 9.3.- Thread types: triangular (metric and Whitworth systems), trapezoidal, round, and sawtooth. 9.4.- Standardized representation of threaded elements. 9.5.- Bolts and studs. 9.6.- Accessories: Washers, Pins, Immobilization and braking systems for screws and nuts. 9.7.- Keyed joints. Topic 10: Fixed joint systems. 10.1.- Introduction to welding. 10.2.- Graphic and symbolic representation of welds. Most common types. 10.4.- Weld designation. Explanatory notes. Block 4 Topic 11: Representation Systems-CAD I. 11.1.- General principles. 11.2.- CAD fundamentals. 11.3.- Distances 11.3.1.- Between two points. 11.3.2.- From a point to a plane, minimum and with a given slope. 11.3.3.- Between two parallel lines, minimum and with a given slope. 11.3.4.- From a point to a line, minimum and with a given slope. 11.3.5.- Between two planes, minimum and with a given slope. 11.3.6.- Minimum distance between two intersecting lines. Topic 12: Representation Systems-CAD II (angles). 12.1.- Direct problems. 12.1.1.- Angle between two lines. 12.1.2.- Angle formed by a line with the PPP. 12.1.3.- Angle between two planes. 12.1.4.- Angle formed by a plane with the PPP. Topic 13: Representation Systems-CAD II (plane sections). 13.1.- Definition and concept of Plane Sections. 13.2.- General Procedures. Intersection with lateral edges. 13.3.- General Procedures. Changes of plane. 13.4.- General Procedures. Homology. 13.5.- True magnitude of the section. 13.6.- Development and transformation of the section. 13.7.- Special cases. Planes parallel to the PPP. 13.8.- Special cases. Projecting planes. 13.9.- Special cases. Parallel planes. |
| 199 | Degree in Telecommunications Technology Engineering | 1990095 | 3D Animation Techniques (SI) | Semester 2 | Principles of 3D animation. Modeling and simulation of dynamic environments and elements. Integrating content into virtual and augmented reality experiences. |
| 208 | Degree in Chemical Engineering | 2080016 | Applied Chemical Kinetics and Thermodynamics | Semester 2 | Applications of chemical equilibrium. Estimation of properties. Kinetics of homogeneous and heterogeneous reactions. Catalysis |
| 199 | Degree in Telecommunications Technology Engineering | 1990036 | Radiocommunication Fundamentals | Semester 2 | Basic antenna parameters. Radiocommunication subsystems. Transmitter and receiver characteristics. Radio propagation. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630010 | Business Management Tools | Semester 2 | 1. Financial analysis and management. 2. Commercial management. |
| 225 | Degree in Civil Engineering | 2250033 | General Construction Procedures | Semester 2 | Construction procedures for: excavation and blasting, backfill formation, drilling and tunneling, drainage systems, concrete works, and steel structures; construction and auxiliary machinery; construction organization and planning techniques; measurement and economic evaluation; health and safety; resource and environmental management; and control during the construction process. |
| 208 | Degree in Chemical Engineering | 2080021 | Theory of Machines and Mechanisms | Semester 2 | Schematic representation of mechanisms. Introduction to the kinematic and dynamic analysis of mechanisms. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990009 | Reactor Engineering | Semester 2 | Multiphase reactors. Fixed-bed catalytic reactors. Fluidized-bed reactors. Three-phase reactors |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990015 | Advanced Simulation of Chemical Processes | Semester 2 | The subject is divided into two thematic blocks, each one related to the two types of tools or approaches to process simulation in chemical engineering: Block 1: Steady-state process simulation with commercial simulators Block 2: Analysis and design of process equipment using CFD simulation The first block will explain the functionalities and general characteristics of process simulators and those of the simulator selected for the subject. Aspects such as property calculation, selection and adjustment of thermodynamic methods, process unit models, convergence strategies, analysis tools and energy integration will be addressed. The second block will explain the fundamentals and methodologies for solving engineering problems using CFD techniques. The main objective of this part is to learn how to use a commercial CFD program in user mode, although an introduction to the bases and fundamentals of calculation will be made to understand the numerical methods and resolution schemes used by a commercial CFD simulator. Likewise, emphasis will be placed on understanding the structure of the conservation equations that govern the problems, the specific sub-models to be implemented in each particular case, their dominant parameters and the importance of creating an adequate mesh, applying the appropriate boundary conditions to the computational domains and performing a critical analysis of the solution. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210015 | Thermodynamics | Semester 1 | Block I (2.5 weeks): BASIC CONCEPTS 1. INITIAL CONCEPTS 2. ZERO PRINCIPLE: THERMAL EQUATIONS OF STATE Block II (4 weeks): THERMODYNAMIC ANALYSIS OF SIMPLE SYSTEMS 3. FIRST PRINCIPLE: ENERGY EQUATIONS OF STATE 4. SECOND PRINCIPLE 5. ENTROPY; ENTROPY EQUATIONS OF STATE 6. EXERGY; EXERGETIC EQUATIONS OF STATE Block III (2 weeks): FORMALISMS OF THERMODYNAMICS 7. THERMODYNAMIC POTENTIALS 8. EQUILIBRIUM AND STABILITY Block IV (2 weeks): THERMODYNAMIC ANALYSIS OF NON-REACTING COMPOUND SYSTEMS 9. PARTIAL MOLAR MAGNITUDES 10. EQUATIONS OF STATE OF COMPOUND SYSTEMS Block V (3.5 weeks): APPLICATIONS 11. NOTIONS ABOUT THERMODYNAMIC CYCLES LABORATORY PRACTICES |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560030 | Expansion of Elasticity and Resistance of Materials | Semester 2 | Stresses, strains, laws of behavior, yielding criteria. Principles and theorems of elasticity. Plane states. Finite elements. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560043 | Hydraulic machines | Semester 1 | Fluid dynamics around solid bodies. Introduction to hydraulic systems. Characterization of hydraulic machines. Pressure, level, and flow measurement in hydraulic systems. Calculation of hydraulic and pneumatic systems. Compressibility effects in pipeline networks. |
| M143 | Master's Degree in Aeronautical Engineering | 51430002 | Automatic Control Plugins | Semester 2 | Fundamentals of automatic control. Analysis of dynamical systems in the time domain. Analysis of linear models of dynamical systems in the frequency domain. Stability. Control methods. Computer control. Basic principles of flight control and automation. |
| M146 | Master's Degree in Industrial Engineering | 51460086 | Vehicle Control | Semester 2 | 1. Introduction to Automotive Control 2. Modeling for Automotive Control 3. Propulsion System Control. Electric and Hybrid Vehicle Control 4. Dynamics Control: Traction, Stability, and Braking 5. Other Controls 6. Introduction to Intelligent Transportation Systems |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630007 | Quantitative Decision-Making Tools | Semester 1 | 1. Modeling and optimization 2. Linear programming 3. Integer programming |
| M181 | Master's Degree in Chemical Engineering | 51810013 | Engineering and Supervision of Chemical Plants | Semester 2 | Block I: Engineering project in a chemical plant Introduction to design. Strategies Organization and planning of a project Project planning and design software Documentation and drawings Permitting Industrial legalization Purchase management Block II: Regulations and regulations Storage of chemical products - Fuels Pressure equipment - Boilers Industrial insulation Legionella control and maintenance of cooling towers Fluid propulsion and solid transport equipment Industrial safety and hygiene Block III: Equipment and instrumentation design Boilers. Boiler water conditioning. Propulsion equipment Exchangers Cooling towers Absorption columns Storage tanks Instrumentation Valves Connections. Flanges. Fittings Block IV: Layout of a chemical plant Equipment implementation Piping Support Equipment assembly Block V: Supervision and analysis of chemical processes Estimation of investment and operation costs Data acquisition systems Industrial process control systems Start-up, operation and shutdown manuals Safety plans. Emergency response |
| M190 | Master's Degree in Civil Engineering (2019) | 51900025 | Structural Typology and Bridges | Semester 2 | A) Structural Typology B) Bridge Typology C) Specific Calculations |
| 199 | Degree in Telecommunications Technology Engineering | 1990053 | Organization Engineering | Semester 1 | Introduction to entrepreneurship. Business management techniques. Project and team management. Decision support systems. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900017 | Advanced Mathematical Methods in Civil Engineering | Semester 1 | 1 Stability and bifurcations in mechanical systems. 2 Nonlinear equations and systems of equations. 3 Partial differential equations. |
| 203 | Degree in Industrial Technology Engineering | 2030072 | Chemical analysis | Semester 1 | - Unit operations in chemical analysis. - Chemometrics. - Classical analysis methods. - Spectroscopic methods. - Electrochemical methods. - Separation methods. - Mass spectrometry. - Thermogravimetric methods. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960048 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 208 | Degree in Chemical Engineering | 2080035 | Measurement and Control of Environmental Pollution | Semester 1 | - Environmental pollutants, types, and effects. - Sampling and analysis of pollutants. - Automatic equipment for pollutant analysis. - Waste characterization. - Environmental legislation. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970041 | Metaheuristic Optimization and Prediction in Electrical Systems | Semester 1 | 1. Classification Techniques ¿ Kohonen Networks ¿ Competitive Networks ¿ C-clustering ¿ 2. Prediction Methods. ¿ Ar and Arx Models ¿ Ma, Arma and Armax Models ¿ ARIMA Models ¿ Neural Networks. ¿ Neighbors Technique. 3. Optimization Techniques. ¿ Genetic Algorithms. ¿ Particle Swarm Optimization Algorithms ¿ Tabu Search ¿ Simulated Annealing 4. Introduction to Stochastic Programming |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970037 | Renewable Electricity Generation | Semester 1 | TOPIC 1: INTRODUCTION TOPIC 2: MINI-HYDRAULIC POWER PLANTS. - General characteristics. - Configuration of a mini-hydropower plant. - Components. - Turbine selection. Head. - Flow. - Feasibility study. Typical installations. - Electrical diagram. TOPIC 3: MARINE ENERGY - Wave power systems. - Tidal power. - Ocean currents TOPIC 4: WIND FARMS. - Wind characterization. - Types of turbines. - Types of wind turbines. - Wind resource assessment: wakes, electrical losses and unavailability - Wind power plant cost model: Investment and operating costs - Optimization of wind power plant configuration - Risk and sensitivity to parameters - Repowering TOPIC 5: SOLAR THERMOSATOR INSTALLATIONS TOPIC 6 PHOTOVOLTAIC INSTALLATIONS. - Solar radiation characterization. - Solar cells. - Solar module. - Photovoltaic installation. - Sizing of isolated installations. - Sizing of installations connected to the grid. TOPIC 7: STORAGE TECHNOLOGIES TOPIC 8: CONNECTION REQUIREMENTS. GRID CODES TOPIC 9: SOCIAL AND HEALTH IMPLICATIONS: BENEFITS OF RENEWABLE ENERGY, ENERGY EFFICIENCY AND SELF-CONSUMPTION. |
| 225 | Degree in Civil Engineering | 2250067 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320020 | Unions in aeronautical structures | Semester 2 | Part 1: Welding UNIT I INTRODUCTION Definition and historical aspects. Theoretical and practical knowledge of welded joints. Specific characteristics of welds. Advantages and disadvantages of welded joints. Classification of welding procedures. Fusion welding. Solid-state welding. Brazing and soldering. UNIT II WELDING TECHNIQUES Oxyacetylene welding. Spot welding. Continuous or roll welding. Bump welding. Pure resistance butt welding. Spark welding. Electric arc welding. Shielding gas welding (TIG and MIG/MAG). Automatic welding. Other welding techniques. UNIT III INTRODUCTION TO THE DESIGN AND CALCULATION OF WELDED JOINTS. Aspects of the welded joint that influence the in-service behavior of a structure. Factors to consider for the analysis and design of welded joints. Mechanical properties of the metals to be joined. Type and nature of loads. Design for static loads. Design for fatigue loads. UNIT IV QUALITY CONTROL. PATHOLOGY AND INSPECTION OF WELDED JOINTS Introduction. Considerations on quality control in welded joints. Inspection of welded joints. Generation and classification of discontinuities. Influence of different welding parameters in the generation of discontinuities. External discontinuities. Internal discontinuities. Standardization. Part 2: Joining by mechanical procedures UNIT I INTRODUCTION Definition. Specific characteristics of mechanical joints. Classification. UNIT II JOINTING ELEMENTS Joints with permanent fixings. Selection parameters and types of rivets. Other joining elements. UNIT III JOINT DESIGN AND FAILURE ANALYSIS Types of failures. Load transmission mechanisms. Calculation of riveted joints. Influence of the type of rivet, material and stress. Load distribution. Risk factors - TOPIC IV EXECUTION OF JOINTS Assembly precautions. Typical joints. Most common defects. Preparation of surfaces to be joined and execution. Installation. Tools. Machines PART 3: Bonding with adhesives TOPIC I INTRODUCTION Definition. Specific characteristics of adhesive joints. Typology of joints. Types of adhesives and fields of application. Selection of adhesives. TOPIC II ADHESIVE TESTS. QUALITY REQUIREMENTS Physical and chemical tests of adhesives. Mechanical tests on glued joints. Reception and qualification standards for adhesives. Reception process. Quality requirements TOPIC III MECHANICAL BEHAVIOUR OF GLUED JOINTS. Characterisation of the stress state in overlap joints. Simplified analysis models for single overlap joints, double overlap joints, bevelled joints and staggered joints. Numerical models. Effect of curing temperature, unequal adhesives, and load type. UNIT IV: DESIGN OF ADHESIVE JOINTS. Metal-to-metal bonded joints. Composite bonded joints. Composite-to-composite bonded joints. Failure mechanisms. Failure criteria. Design curves. |
| 197 | Degree in Aerospace Engineering | 1970010 | General chemistry | Semester 2 | Structure and states of matter. Physicochemical systems and transformations. Properties of chemical reactions: kinetics, spontaneity, equilibrium. Organic chemistry. CHAPTER I. INTRODUCTION TO CHEMISTRY Topic 1. Introduction. Stoichiometry Topic 2. Thermochemistry. Energy changes in chemical reactions CHAPTER II. STATES OF MATTER Topic 3. General properties and states of matter Topic 4. Gases. Gas laws Topic 5. Liquids and solutions CHAPTER III. KINETICS AND EQUILIBRIUM Topic 6. Chemical kinetics Topic 7. Spontaneity and material equilibrium |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970044 | Digital Measurement and Protection Systems for Electrical Systems | Semester 1 | Introduction to electrical measurements Basic mathematical treatment in Digital Signal Processing Discrete transforms Simulation tools Moving window treatment Harmonic calculation Fast algorithms for DFT Application to digital protections Introduction to wavelet transforms |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560008 | Computing | TO | Computer fundamentals. Algorithms. Programming. Introduction to operating systems, databases, and software with applications in engineering. |
| 208 | Degree in Chemical Engineering | 2080018 | Fundamentals of Automatic Control | Semester 1 | Dynamic systems analysis. Frequency analysis. Stability. PID controllers. |
| 199 | Degree in Telecommunications Technology Engineering | 1990009 | Device and Component Technology | Semester 2 | Introduction to electronics. Solid-state physics. Diodes, bipolar transistors, and field-effect transistors. Basic photonic devices. Semiconductor technology. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900003 | Roads | Semester 2 | Part I: Basic characteristics of the road system Topic 1. Road networks Topic 2. Activities of Highway Engineering Topic 3. Highway administrations Topic 4. Vehicles Topic 5. The driver and the pedestrian Part II: Highway planning. Traffic studies. Topic 6. Characteristic variables of road traffic Topic 7. Traffic studies Topic 8. Capacity and service levels in continuous circulation. Topic 9. Capacity and service levels at junctions Topic 10. Highway planning and planning Topic 11. Evaluation of alternatives Part III Geometric design Topic 12. Basic parameters of the layout Topic 13. The trajectory of vehicles Topic 14. Elements of the layout in plan Topic 15. Elements of the layout in elevation Topic 16. Coordination between the plan and the elevation Topic 17. Integration into the environment. Topic 18. The cross section Topic 19. Junctions, intersections and links. Part IV Road studies Topic 20. Inventories Topic 21. Scope of road studies Topic 22. Measurement and compensation of earthworks Topic 23. Operations prior to earthworks Part V Traffic planning, regulation and control Topic 24. Objectives and functions of road network operation. Topic 25. Elements supporting operation. Topic 26. Road aids. Incident management. Topic 27. Traffic management on high-capacity roads. Topic 28. Traffic management in urban areas. Part VI Road safety Topic 29. The problem of road traffic safety Topic 30. Collection and analysis of accident data Topic 31. Improving safety on service roads Topic 32. Road safety in road studies. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270061 | Diagnosis and Management Control | Semester 2 | -Techniques for diagnosing the various subsystems of a company. -Control Theory. -Budgetary and non-budgetary control. -Control in the various areas of a company. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210041 | Electrical Power Systems (EL) | Semester 2 | Power grid modeling and analysis. Load sharing. Contingency analysis . Transient stability. Short-circuit calculation in mesh networks. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560019 | Thermodynamics | Semester 2 | S01 Initial Concepts S02 Zeroth Principle. Thermal Equations of State S03 First Principle. Energy Equations of State S04 Second Principle S05 Entropy. Entropic Equations of State S06 Thermodynamic Potentials S07 Exergy. Exergy Equations of State S08 Equilibrium and Stability S09 Notions of Thermodynamic Cycles S10 Partial Molar Magnitudes S11 Chemical Potential S12 Dependence of Thermodynamic Functions on Composition S13 Thermodynamic Equations of Mixtures S14 Thermodynamic Equations of Mixtures: Applications S15 Chemical Reactions S16 Combustion Thermodynamics |
| M146 | Master's Degree in Industrial Engineering | 51460056 | Advanced Supply Chain Design and Management | Semester 2 | Advanced models for supply chain design and management Coordination in supply networks |
| 225 | Degree in Civil Engineering | 2250017 | Rational mechanics | Semester 1 | Rigid body mechanics. Analytical mechanics |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040024 | AI in Medical Imaging | Semester 1 | Block 1: Physical principles of medical image acquisition modalities Block 2: Medical image analysis using artificial intelligence. Applications |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040030 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210055 | Expansion of Industrial Constructions (DECI) | Semester 1 | Pipe and tank installations. Fire protection installations in pipelines and tanks. Water supply infrastructure. Sewerage and sanitation infrastructure. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270057 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210002 | Process Analysis and Design (OGSP) | Semester 1 | Analysis of industrial and service processes. Types of production processes. Design and improvement of production processes. |
| M143 | Master's Degree in Aeronautical Engineering | 51430021 | Aircraft Structural Design | Semester 1 | The syllabus is grouped into two large blocks: 1.- Certification. 2.- Structural Design. Developed Syllabus: 1 Certification 1.1 Introduction to aircraft structural design 1.2 Aviation safety. Aircraft accident investigation 1.3 Aircraft certification 1.4 Flight standards. Actions 1.5 Flight standards. Flight qualities 1.6 Introduction to structural calculation standards 1.7 Flight loads. Symmetrical maneuvers 1.8 Gust loads 1.9 Gust attenuation factor 1.10 Flight loads. Symmetrical maneuvers 1.11 Ground loads. Landing 1.12 Ground loads. Rolling and Parking 1.13 Fatigue and Damage Tolerance 2 Structural Design 2.1 Allowable Forces 2.2 Diagonal Tension 2.3 Stability of Stringers 2.4 Design of Panels Subjected to Compression 2.5 Sizing of Joints 2.6 Lightening of Panels and Doors 2.7 Composite Design 2.8 Structural Design of Wings 2.9 Structural Design of Fuselages 2.10 Structural Design of Tails 2.11 Structural Design of Pylons 2.12 Structural Design of Trains |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210141 | Electronic Systems for Aerospace Applications | Semester 2 | It has four thematic blocks: Block I. Testing and qualification of electronic components Block II. Testing and qualification of complex electronic systems Block III. Design for qualification of programmable electronic devices for aeronautics and space Block IV. Design of aerospace systems |
| M143 | Master's Degree in Aeronautical Engineering | 51430040 | Unions in aeronautical structures | Semester 2 | Part 1: Welding UNIT I INTRODUCTION Definition and historical aspects. Theoretical and practical knowledge of welded joints. Specific characteristics of welds. Advantages and disadvantages of welded joints. Classification of welding procedures. Fusion welding. Solid-state welding. Brazing and soldering. UNIT II WELDING TECHNIQUES Oxyacetylene welding. Spot welding. Continuous or roll welding. Bump welding. Pure resistance butt welding. Spark welding. Electric arc welding. Shielding gas welding (TIG and MIG/MAG). Automatic welding. Other welding techniques. UNIT III INTRODUCTION TO THE DESIGN AND CALCULATION OF WELDED JOINTS. Aspects of the welded joint that influence the in-service behavior of a structure. Factors to consider for the analysis and design of welded joints. Mechanical properties of the metals to be joined. Type and nature of loads. Design for static loads. Design for fatigue loads. UNIT IV QUALITY CONTROL. PATHOLOGY AND INSPECTION OF WELDED JOINTS Introduction. Considerations on quality control in welded joints. Inspection of welded joints. Generation and classification of discontinuities. Influence of different welding parameters in the generation of discontinuities. External discontinuities. Internal discontinuities. Standardization. Part 2: Joining by mechanical procedures UNIT I INTRODUCTION Definition. Specific characteristics of mechanical joints. Classification. UNIT II JOINTING ELEMENTS Joints with permanent fixings. Selection parameters and types of rivets. Other joining elements. UNIT III JOINT DESIGN AND FAILURE ANALYSIS Types of failures. Load transmission mechanisms. Calculation of riveted joints. Influence of the type of rivet, material and stress. Load distribution. Risk factors - TOPIC IV EXECUTION OF JOINTS Assembly precautions. Typical joints. Most common defects. Preparation of surfaces to be joined and execution. Installation. Tools. Machines PART 3: Bonding with adhesives TOPIC I INTRODUCTION Definition. Specific characteristics of adhesive joints. Typology of joints. Types of adhesives and fields of application. Selection of adhesives. TOPIC II ADHESIVE TESTS. QUALITY REQUIREMENTS Physical and chemical tests of adhesives. Mechanical tests on glued joints. Reception and qualification standards for adhesives. Reception process. Quality requirements TOPIC III MECHANICAL BEHAVIOUR OF GLUED JOINTS. Characterisation of the stress state in overlap joints. Simplified analysis models for single overlap joints, double overlap joints, bevelled joints and staggered joints. Numerical models. Effect of curing temperature, unequal adhesives, and load type. UNIT IV: DESIGN OF ADHESIVE JOINTS. Metal-to-metal bonded joints. Composite bonded joints. Composite-to-composite bonded joints. Failure mechanisms. Failure criteria. Design curves. |
| M143 | Master's Degree in Aeronautical Engineering | 51430015 | Advanced fluid and aerodynamic mechanics | Semester 1 | 1. Introduction to turbulence. Energy cascade concept and Kolmogorov scales. Apparent stress tensor. Reynolds equations. Wall turbulence. Turbulence models. Numerical simulations of turbulent flows. 2. Introduction to compressible flows. Equations of motion. 2-D transonic flow. 3. Thermal boundary layer. Forced convection. Natural convection. 4. Computational Fluid Dynamics (CFD). Mesh generation. Solver. Convergence. Mesh refining. Commercial software and free software. 5. Passive scalars. Multi-phase flows. ----------------- ENGLISH: 1. Introduction to turbulence. Energy cascade concept and Kolmogorov scales. Apparent stress tensor. Reynolds equations. Wall turbulence. Turbulence models. Numerical simulations of turbulent flows. 2. Introduction to compressible flows. Equations of compressible flows. 2-D transonic flow. 3. Thermal boundary layer. Forced convection. Natural convection. 4. Computational fluid dynamics (CFD). Mesh generation. Resolution. Mesh refinement. Convergence. Current commercial and free software. 5. Passive scalar flow. Two-phase flows. |
| M146 | Master's Degree in Industrial Engineering | 51460093 | Distribution Systems Control | Semester 2 | BLOCK I Modeling and Machine Learning. I.1 Modeling and Simulation of Distribution Systems: I.2 Machine Learning Techniques: I.3 Estimation. Kalman Filter. I.4. Data Reconciliation and Fault Detection. BLOCK II Planning and Control of Distribution Systems II.1 Economic Planning. II.2. Constrained Control. BLOCK III. Numerical Optimization Techniques. III.1 Quadratic Problems. III.2 Gradential Optimal Methods. |
| M146 | Master's Degree in Industrial Engineering | 51460053 | Dynamics of Multibody Systems | Semester 2 | The course consists of two thematic blocks: - Computational Kinematics - Computational Dynamics The first block, Computational Kinematics, shows the machine modeling techniques for simulation, including the selection of coordinates and reference systems and the kinematic restrictions to which they are subject. Based on the model, the computational techniques for analyzing position, velocity and acceleration that allow kinematic simulation are shown. The second block, Computational Dynamics, shows the automatic formulation and calculation of the equations of motion of multibody systems in their ODE and DAE forms. The block continues by showing the numerical methods for solving these equations in the time domain that allow the dynamic simulation of machines. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630002 | Advanced Supply Chain Design and Management | Semester 2 | Advanced models for supply chain design and management Coordination in supply networks |
| 199 | Degree in Telecommunications Technology Engineering | 1990008 | Mathematics III | Semester 2 | Knowledge of advanced aspects of Mathematical Analysis and its applications: differential equations, Laplace transform, systems of differential equations, Fourier analysis, partial differential equations. |
| M164 | Master's Degree in Electrical Energy Systems | 51640003 | Communications, Remote Control and Automation of Electrical Systems | Semester 1 | I. Basic communication concepts (modulation, multiplexing, transmission media, communication networks) II. Automation of the electrical transmission network III. Automation of distribution networks |
| 199 | Degree in Telecommunications Technology Engineering | 1990098 | Digital Processing of Medical Images | Semester 2 | Physical principles of different medical image acquisition sources. Medical image analysis. Applications of medical imaging. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920044 | Nonlinear Continuum Mechanics | Semester 1 | BLOCK 1: Introduction to Nonlinear Continuum Mechanics. Lesson 1.- A first contact with nonlinear deformable solid mechanics. Lesson 2.- Contact boundary condition in the elastic problem. BLOCK 2: The linear and nonlinear elastic solid with large deformations. Lesson 3.- Kinematics of deformable solids Lesson 4.- Conservation principles Lesson 5.- Behavioral relation Lesson 6.- Formulation of the elastic problem Lesson 7.- Variational structure of the elastic problem Lesson 8.- Viscoelastic materials BLOCK 3: The perfect elastoplastic solid with small deformations. Lesson 9.- Plasfication criteria Lesson 10.- The perfect elastoplastic model Developed program BLOCK 1: Introduction to Nonlinear Continuum Mechanics. Lesson 1.- A first contact with nonlinear deformable solid mechanics. 1.1 Introduction. 1.2 Review of the elastic problem. 1.3 Sources of nonlinearity. 1.4 Boundary conditions. Lesson 2.- Contact boundary condition in the elastic problem. 2.1 Introduction. 2.2 Frictionless contact (2D and 3D) 2.3 Frictional contact (2D and 3D) 2.4 Numerical solution methodologies in Finite Element codes. BLOCK 2: The linear and nonlinear elastic solid with large deformations. Lesson 3.- Kinematics of deformable solids 3.1.- Configuration space. Motion, velocity and acceleration 3.2.- Strain gradient 3.3.- Strain tensors 3.4.- Polar decomposition of the strain gradient 3.5.- Physical interpretation of the components of the strain tensor 3.6.- Strain tensors under the hypothesis of small deformations and displacements 3.7.- Time derivative of the strain tensors Lesson 4.- Conservation principles 4.1.- Stress tensors in large displacements 4.2.- Fundamental law of conservation 4.3.- Conservation of mass (CM) 4.4.- Theorem of variation of the momentum (VCM) 4.5.- Theorem of variation of the kinetic momentum (VMC) 4.6.- Conservation of energy (CE) 4.7.- Second law of thermodynamics 4.8.- Compliance with the principles of conservation. Green-Naghdi-Rivlin theorem 4.9.- Entropy production. Gibbs condition Lesson 5.- Behavioral relation 5.1.- Behavioral relation. Typologies of materials 5.2.- Behavioral relation for elastic materials 5.2.1.- Conditions for the behavioral relation 5.2.2.- Behavioral relation as a function of the free energy function 5.2.3.- Elastic tensors 5.2.4.- Spatial version of the behavioral relation for elastic materials in isothermal processes 5.2.5.- The elastic material as a hyperelastic material. Strain energy density function 5.3.- Elastic materials with symmetries 5.3.1.- Homogeneous elastic materials 5.3.2.- Isotropic elastic materials 5.4.- Hyperelastic materials 5.4.1.- Isotropic hyperelastic materials 5.4.2.- Behavior of the strain energy density function for large deformations 5.4.3.- Classical hyperelastic models Lesson 6.- Formulation of the elastic problem 6.1.- Strong statement of the problem of nonlinear elastodynamics 6.2.- Weak statement of the problem of nonlinear elastodynamics 6.3.- Mathematical basis of linear elastostatics Lesson 7.- Variational structure of the elastic problem 7.1.- Hamiltonian structure of nonlinear elastodynamics 7.2.- The Minimum Potential Energy Theorem in elastostatics linear 7.3.- Other variational principles BLOCK 3: The perfect elastoplastic solid with small deformations. Lesson 8.- Plasmid criteria 8.1.- Introduction. 8.2.- Definition of the plasmid criterion. 8.3.- Experimental evidence. 8.4.- General characteristics. 8.5.- Tresca criterion. 8.6.- von Mises criterion. 8.7.- Comparison with experiments. Lesson 9.- The perfect elastoplastic model 9.1.- The one-dimensional case. Basic postulates. 9.2.- The three-dimensional case. 9.3.- Equivalent stress and equivalent plastic strain. 9.4.- Inverse behavior law. 9.5.- Uniqueness theorem. 9.6.- Plastic collapse. 9.7.- Limit analysis 9.8.- Uniqueness in Limit Analysis. 9.9.- Limit analysis of plane problems. |
| M228 | Master's Degree in Operation of Space Systems | 52280004 | Electronic Components and Systems for Space | Semester 2 | Testing and qualification of electronic components; Testing and qualification of complex electronic systems; Design for qualification of programmable electronic devices for space; Design of space electronic systems |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980042 | Simulation and Optimization of Thermal Energy Systems | Semester 1 | Part I: Thermal Systems Optimization Lesson 1. Introduction to Simulation and Optimization of Thermal Processes Lesson 2. Basic Design Considerations Lesson 3. Introduction to Modeling and Simulation of Thermal Processes Lesson 4. Simulation of Thermal Processes Lesson 5. Optimization of Thermal Systems Lesson 6. Cost Estimation and Economic Analysis of Thermal Processes Lesson 7. Applications in the Design of Heat Exchangers Part II: Heat Exchanger Networks Lesson 8. Heat Exchanger Networks Part III: Simulation of Thermal Systems Lesson 9: Dynamic Simulation of Thermal Systems (EES) Lesson 10: Characterization of Thermal Systems Using Performance Curves Lesson 11: Dynamic Simulation of Thermal Systems (EXCEL) |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280062 | Instrumentation and Signal Conditioning | Semester 2 | |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210016 | Thermal Power Generation (EN) | Semester 1 | Furnaces and boilers. Heat transfer in homes. Energy-saving measures for thermal generators. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280030 | Electronic Instrumentation | Semester 2 | Operating principles of sensors and actuators. Electronic instrumentation techniques. Signal conditioning principles. |
| M143 | Master's Degree in Aeronautical Engineering | 51430055 | Cartography applied to drones | Semester 2 | Theoretical Content: - Topic 1: Terrestrial reference system and types of coordinates - Topic 2: Projections and cartographic products - Topic 3: Geographic Information Systems and SDI services - Topic 4: The LIDAR system and Digital Terrain Models - Topic 5: Basic principles of Photogrammetry - Topic 6: Cartographic survey - Topic 7: Precise positioning with GPS Practical Content - Practice 1: The navigator and topographic GPS. SRT changes. - Practice 2: Uses of cartographic projections - Practice 3.1: Geospatial data management - Practice 3.2: Aeronautical maps and charts - Practice 4: LiDAR - Practice 5: Flight planning - Practice 6: Cartographic survey |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930041 | Waste Engineering | Semester 1 | Domestic waste: collection and management. Characterization and treatment of hazardous waste. Biological treatments. Thermal treatment. Waste landfill. Radioactive waste. Soil reclamation. Topic 1. Introduction. Waste. General problems. Topic 2. Legislation. Characterization of domestic and commercial waste. Management and characterization of hazardous waste. Topic 3. Urban waste management and collection systems. Recycling. Topic 4. Urban waste processing and separation technologies . Topic 5. Biological waste treatment. Composting. Anaerobic digestion. Topic 6. Thermal treatment of waste. Topic 7. Physicochemical treatment of hazardous waste. Topic 8. Stabilization-solidification treatments of hazardous waste. Topic 9. Waste landfill. Topic 10. Radioactive waste management. Topic 11. Consumer goods waste management. |
| M143 | Master's Degree in Aeronautical Engineering | 51430012 | Aeroelasticity | Semester 2 | 1. Introduction to Aeroelasticity 2. Static Aeroelasticity 3. Unsteady Potential Aerodynamics 4. Dynamic Aeroelasticity. Flutter at Small Angles of Attack 5. Gusts 6. Flapping and Separation Flutter 7. Experimental Aeroelasticity and Civil Aeroelasticity |
| 225 | Degree in Civil Engineering | 2250038 | Civil constructions | Semester 1 | Teaching will be provided through theoretical classes given by the professor, distributed into THEMATIC BLOCKS, in accordance with the contents specified by the descriptors of the Study Plan, which have been expanded with some content that is considered essential for the training of excellent professionals qualified by the degree studies. BLOCK I - TENDERING, CONTRACTING AND EXECUTION OF PUBLIC WORKS This block will cover the aspects of tendering, awarding and contracting of civil works; planning and production of the execution and quality management of public works. It will be complemented by the study of quality control of public works according to international standards (ISO 9000 and ISO 14000). Just as the student will be introduced to construction planning and its programming using GANTT and PERT techniques using advanced computer programming tools and others with BIM models . BLOCK II - DIGITAL CONSTRUCTION WITH BIM TECHNOLOGY. In this block, the basic concepts of digital construction with BIM tools under the UNE-EN ISO19.650 standard will be developed. And the innovative digital construction (construction 4.0) through learning BIM modeling techniques: - The BIM conception and modeling of linear civil infrastructures - The BIM conception and modeling of (i) building structures including their foundations, (ii) bridges, and (iii) dams. Prior to modeling BUILDING STRUCTURES, the Design and Dimensioning of this type of structures will be addressed, through the application of current regulations. BLOCK III - CONSTRUCTION AND CONSERVATION OF PAVERS IN TRANSPORT INFRASTRUCTURES. The design of the pavement and its foundation will be addressed, applying pavement mechanics with modeling of its structure and loads, to obtain the stress state and the deformations that occur in response to stresses. Analytical and empirical methods for pavement sizing will be studied by examining the applicable technical regulations, such as the Pavement Instructions for the Andalusian Road Network and the Highway Instructions of the Ministry of Public Works, as well as the applicable computer applications. The construction processes (i) of the Earth Structure, (ii) of the Firm Foundation, as well as (iii) the construction of Also in this block, the basic concepts of conservation management and inventory techniques will be developed, as well as the Pathology and Auscultation of roads, and the Techniques for the conservation of roads . In particular, the contents on: - the technical specifications required for the construction materials applied in the works covered by the scope of the subject, and their quality control, will be developed - the construction techniques applied in the indicated constructions, with the study of the material means and machinery equipment to be used, as well as their performance. - the procedures (activities) applied in their execution, as well as their quality control. - and the innovative digital construction (construction 4.0) through the learning of BIM modeling techniques and collaborative practical classes will be held by the students (Workshops), following the syllabus, through Practical Cases, distributed in the different thematic blocks in which the subject has been structured. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900028 | Professional Practice of Engineering | Semester 2 | 1. INTRODUCTION TO ENGINEERING. APPLICATION TO THE CASE OF INDUSTRIAL ENGINEERING a. HISTORY b. PROFILE c. WORKS d. RECOGNITIONS 2. THE ENGINEERING MAP. APPLICATION TO INDUSTRIAL ENGINEERING a. SPANISH ENGINEERING FIRMS b. ENGINEERING FIRMS WORLDWIDE c. ENGINEERING ORGANIZATIONS d. PROFESSIONAL ASSOCIATIONS e. PROFESSIONAL ENGINEERING CERTIFICATIONS f. ENGINEERING DEGREES g. THE PRACTICE OF ENGINEERING AROUND THE WORLD h. INDUSTRIAL ENGINEERING STUDIES i. SOFT SKILLS FOR WORKING AS AN ENGINEER j. SUCCESS IN THE ENGINEERING PROFESSION 3. THE LEGISLATIVE FRAMEWORK OF THE ENGINEER a. COMPETENCES, ATTRIBUTIONS AND COMPETENT TECHNICIANS b. PROFESSIONAL ATTRIBUTIONS OF THE ENGINEER. ATTRIBUTIONS OF THE INDUSTRIAL ENGINEER c. PROJECT DRAFTING d. PROFESSIONAL FEES e. INDUSTRIAL LEGISLATION, RULES AND REGULATIONS f. SUBMISSION OF DOCUMENTS TO THE ADMINISTRATION g. REGULATION OF THE PROFESSION IN VARIOUS COUNTRIES h. THE CIVIL AND CRIMINAL LIABILITY OF THE ENGINEER i. JUDGMENTS FOR ATTRIBUTIONS j. JUDGMENTS FOR CIVIL LIABILITY k. PROFESSIONAL ETHICS l. COLLEGE VISA 4. FIELDS OF ACTIVITY OF THE ENGINEER. APPLICATION TO INDUSTRIAL ENGINEERING a. THE ENGINEER IN THE INDUSTRIAL COMPANY b. THE ENGINEER AS A BUSINESS DEVELOPER c. THE ENGINEER IN THE PUBLIC SERVICE d. THE ENGINEER IN THE ENGINEERING COMPANY e. THE ENGINEER IN THE SERVICE COMPANY f. THE ENGINEER IN THE MAINTENANCE COMPANY g. OCCUPATION BAROMETER FOR INDUSTRIAL ENGINEERS 5. THE INDEPENDENT PROFESSIONAL ENGINEER a. TYPES OF SELF-EMPLOYED ENGINEERS b. THE ALTERNATIVE TO THE SPECIAL REGIME FOR SELF-EMPLOYED WORKERS (RETA) 6. FROM BASIC TO DETAIL ENGINEERING a. PHASES OF INDUSTRIAL PROJECT PREPARATION b. BASIC PROJECT INFORMATION c. PERMITS AND LICENSES d. BASIC PROJECT ENGINEERING e. DETAIL ENGINEERING f. PURCHASE MANAGEMENT g. CONSTRUCTION SUPERVISION h. COMMISSIONING 7. ENGINEERING CONTRACTS a. CONTRACT TYPES b. FIDIC CONTRACTS 8. PUBLIC TENDERS a. CONCEPTS b. REQUIREMENTS c. TENDERS d. CONTRACT CONTENT e TENDER DOCUMENTS . PROPOSAL CONTENT 9. LOOKING AT THE COMPANY THROUGH AN ENGINEER'S EYES a. THE COMPANY'S ECOSYSTEM b. KNOWLEDGE ABOUT BUSINESS MANAGEMENT c. FROM MANAGER TO ENTREPRENEUR d. QUALITIES FOR SUCCESS e. WHAT TO DO AND WHAT NOT TO DO f. WHAT OTHERS HAVE ALREADY SAID |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270012 | Thermal Engineering | Semester 1 | Heat transfer. Combustion. Heat exchangers. Power cycles. Applications. |
| 203 | Degree in Industrial Technology Engineering | 2030139 | Industrial Metrology | Semester 2 | PART 1 Introduction to metrology Metrology and business. Standardization. Certification. Testing. Calibration. Inspection. Accreditation. The metrology laboratory. The measuring instrument. Measurement errors. The international system of units. Measurement uncertainty. Final expression of the measurement result PART 2 Dimensional metrology Fits and tolerances. Measuring instruments. Gauges. Surface roughness. Geometric tolerances. Measurement of threads and gears. Functional dimensioning PART 3 Metrology of other quantities Electrical metrology. Pressure measurement. Temperature measurement. Torque measurement |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210050 | Alternative Internal Combustion Engines | Semester 1 | I. INTRODUCTION II. CYCLES: REAL, THEORETICAL AIR AND AIR-FUEL III. CHARGE RENEWAL: FOUR-STROKE AND TWO-STROKE ENGINES IV. COMBUSTION: MECH AND MEC V. MIXTURE FORMATION AND IGNITION VI. EMISSIONS VII. OPERATING CHARACTERISTICS |
| 197 | Degree in Aerospace Engineering | 1970075 | Control and Guidance Systems | Semester 2 | Flight control systems. Stability augmentation systems. Attitude control. Multivariable control. Trajectory control. Synchronized maneuver control. Guidance. |
| 225 | Degree in Civil Engineering | 2250036 | Hydraulic expansion | Semester 1 | Equations governing fluid motion. Potential motions. Boundary layer. Turbulence. |
| 203 | Degree in Industrial Technology Engineering | 2030102 | Heterogeneous Reactors | Semester 1 | Catalytic, gas-solid, gas-liquid, design, simulation and optimization |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320012 | Advanced Flight Mechanics | Semester 1 | Estimation of stability derivatives. Advanced stability and control studies. Flight qualities. Nonlinear dynamics. Gust response. |
| 208 | Degree in Chemical Engineering | 2080054 | Structure Theory | Semester 1 | 1. Basic concepts in industrial structural design: definitions, materials, stresses, structural safety, static and dynamic behavior. 2. Basic structural types: Pin-jointed structures . 3. Matrix design of structures. Introduction to the finite element method: Application to bar structures. 4. Sizing of simple steel structures. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320017 | Aerospace Production | Semester 2 | The Supply Chain in the Aeronautical Industry. Production Management Systems in the Aeronautical Industry. Lean Manufacturing. Final Aircraft Assembly Lines (FAL) |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210030 | Fracture Mechanics (IRM) | Semester 1 | Study of crack propagation. Elastic models (tensional and energy approaches). Elastoplastic models. Characterization of fracture-prone materials. Applications. |
| M143 | Master's Degree in Aeronautical Engineering | 51430023 | Airport Project and Certification | Semester 1 | SUBJECT 1.- AERODROME CERTIFICATION. DEFINITION AND CONCEPTS. INTERNATIONAL AND NATIONAL REGULATORY FRAMEWORK SUBJECT 2.- THE CERTIFICATION PROCESS. SUBJECT 3.- PREPARATION OF THE AERODROME MANUAL. STRUCTURE AND CONTENT. SUBJECT 4.- AERONAUTICAL STUDIES SUBJECT 5.- SAFETY MANAGEMENT SYSTEM (SMS). ---------English version ----------------------- SUBJECT 1.- AERODROME CERTIFICATION. DEFINITION AND CONCEPTS. INTERNATIONAL AND NATIONAL REGULATORY FRAMEWORK SUBJECT 2.- THE CERTIFICATION PROCESS. SUBJECT 3.- DEVELOPMENT OF THE AERODROME MANUAL. STRUCTURE AND CONTENT. SUBJECT 4.- AERONAUTICAL STUDIES SUBJECT 5.- SAFETY MANAGEMENT SYSTEM (SMS). |
| 197 | Degree in Aerospace Engineering | 1970072 | Applied Optics | Semester 2 | Optical observation instruments. Photonics. Digital cameras. 2D and 3D visualization systems and techniques. Non-visible imaging systems. Optical technologies for engineering. |
| M146 | Master's Degree in Industrial Engineering | 51460110 | Micro and Nano Electronics | Semester 2 | 1. Electronic simulation with CADENCE. 2. Hardware description languages for analog circuits. 3. Basic block design. 4. Electronic system design. 5. Analog circuits in aerospace applications. |
| M146 | Master's Degree in Industrial Engineering | 51460060 | Fundamentals and Simulation of Manufacturing Processes | Semester 2 | - Fundamentals of Forming Process Analysis: Plastic Forming; Machining; Non-Conventional Processes. - Design for Manufacturing and Assembly (DFMA). - Manufacturing Process Simulation. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600003 | Distribution Systems Control | Semester 2 | BLOCK I Modeling and Machine Learning. I.1 Modeling and Simulation of Distribution Systems: I.2 Machine Learning Techniques: I.3 Estimation. Kalman Filter. I.4. Data Reconciliation and Fault Detection. BLOCK II Planning and Control of Distribution Systems II.1 Economic Planning. II.2. Constrained Control. BLOCK III. Numerical Optimization Techniques. III.1 Quadratic Problems. III.2 Gradential Optimal Methods. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830009 | Environmental Management in Industry | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830006 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 199 | Degree in Telecommunications Technology Engineering | 1990061 | Telematics Projects | Semester 1 | Block I: Basic Skills for the Development of Telematics Engineering Projects - Communication: Drafting Technical Documents, Technical Project Argumentation, Effective Presentations, Assertive Communication. - Searching for and evaluating information quality. - Group Work: Time management in meetings, negotiation techniques Block II: Project for the design of a Corporate Data Network. (Development and presentation of a group project) Block III: Project for the design of a Corporate Software Application. (Development and presentation of a group project). |
| 199 | Degree in Telecommunications Technology Engineering | 1990022 | Digital Communications | Semester 1 | Elements of a digital communication system. Shannon model. Signal space. Digital transmitters and receivers. Error probability. Digital modulations. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210060 | Advanced Control (AR) | Semester 1 | Block 1 - Advanced Industrial Control Techniques. Block 2 - Multivariable Control. Block 3 - Embedded Industrial Control Systems. Block 4 - Practical Implementation of Controllers. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990026 | Industrial Security | Semester 1 | After a general introduction, the course will be divided into the following fundamental sections: 1. Overview of Industrial Safety. 2. The different stages in the implementation of an ES: Hazard Identification Techniques. 3. The different stages in the implementation of an ES: Consequence Analysis. 4. Quantitative Risk Analysis (RCA). 5. Risk Reduction Techniques applied to the design of chemical plants. 6. Emergency Plan. Inside and outside the factory. |
| 225 | Degree in Civil Engineering | 2250012 | Elasticity | Semester 1 | Stresses. Strain. Laws of behavior. The elastic problem. Thermal effects. Yield criteria. Principles and theorems of elasticity. Plane states. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040007 | Software Factories | Semester 2 | Fundamentals: Process models. Requirements, change, and software quality management. Development environment: continuous integration . Testing environment: continuous testing. Deployment environment: continuous delivery. Operational environment: continuous monitoring. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600009 | Perception in Automatics and Robotics | Semester 2 | 1 Inspection: texture analysis 2 Detection and monitoring: motion, Kalman filter 3 Quality control: K-means, k-distance classifier, RN 4 Localization, mapping: position estimation, environment representation, map creation. |
| 197 | Degree in Aerospace Engineering | 1970001 | Graphic expression | TO | Thematic Blocks Thematic Block I: Representation Systems. Thematic Block II: Normalization. Thematic Block III: Computer-Aided Drawing. Thematic Block I (50% weight). Thematic Blocks II and III (remaining 50% weight). Thematic Block I: REPRESENTATION SYSTEMS Topic 1. Introduction to Representation Systems. Topic 2. Descriptive Geometry. Fundamentals of the dihedral system. Direct method. Topic 3. Applied D. Geometry. Cutting of pieces. Sheet metal. True magnitude. Topic 4. Descriptive Geometry. Curves and technical surfaces. Topic 5. Descriptive Geometry. Intersection of surfaces. Topic 6. Applied D. Geometry. Elbows and Transition Surfaces (Hoppers and Adapters). Topic 7. Fundamentals of axonometric perspectives. Topic 8. Introduction to the system of dimensioned plans. Topic 9. Representation of roofs and rafts. Topic 10. Representation of esplanades and roads. Thematic Block II: STANDARDIZATION Theme 1. General representation principles. Theme 2. Standardization of Technical Drawings. Theme 3. Views, sections and sections. Theme 4. Dimensioning principles. Sketching. Theme 5. Dimensioning with tolerances. Dimension transfer. Theme 6. Functional dimensioning. Theme 7. Standardization of tolerances and fits. Theme 8. Surface states. Geometric tolerances. Theme 9. Joint systems. Removable (threads) and fixed (welds). Theme 10. Analysis and interpretation of mechanical assemblies. Assembly and exploded view. Theme 11. Standardized machine elements. Theme 12. Standardized symbols. Thematic Block III: COMPUTER-ASIDED DRAWING Theme 1. Introduction to CAD systems. Theme 2. Creation and layout of flat representations. Theme 3. 3D part modeling. |
| M143 | Master's Degree in Aeronautical Engineering | 51430034 | Aerospace Robotics | Semester 2 | INTRODUCTION TO AEROSPACE ROBOTICS: Robotics and aerospace robots. CONCEPTS AND METHODS IN ROBOTICS: Robot modeling and control. ORBITAL ROBOTICS: Robots for in-orbit and space station services. EXPLORATION ROBOTICS: Rovers for exploring planets, satellites, and asteroids. INTRODUCTION TO AERIAL ROBOTICS: Flying robots, aerial robotic manipulation, functionalities, and applications. INTRODUCTION TO ROBOTICS FOR AERONAUTICAL MANUFACTURING: Applications of manipulator and mobile robots in aeronautical manufacturing. |
| M143 | Master's Degree in Aeronautical Engineering | 51430053 | Propulsion Accessories | Semester 1 | Propeller Propulsion Systems. Jet Aircraft Propulsion Systems. Space Propulsion Systems. |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950039 | Refining and Petrochemicals | Semester 1 | Block I: Oil Industry Crude Oil Extraction (conventional and non-conventional processes) Desalination and Pretreatments Evaluation of Crude Oil Distillation (topping), obtaining LPG and Vacuum Distillation Hydrotreatments (HDS, Hydrocracking) Catalytic Reforming and FCC Alkylation and Isomerization Other treatments Hydrogen in refinery Block II: Petrochemicals Production of Benzene and its derivatives Production of Olefins and its derivatives Production of Methanol and its derivatives Block III: Expert seminars |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210037 | Savings in Energy Demand | Semester 1 | Introduction: Heat and aeraulic transmission in buildings. Equation formulation. External stresses. 1D conductive heat transmission. Fundamentals of CTE-HE1. Conductive heat transmission (special cases and thermal bridges). Materials and products databases and thermal bridges (DA HE3). Semi-transparent enclosures. Solar control. Ventilation / Infiltration. Detailed model I: analysis of results and diagnosis. Simplified model: global characterization of spaces and buildings. Detailed model II: global characterization of spaces and buildings. Simplified model: global demand reduction strategies: indicators. Optimal energy / economic design I: LCCA, databases, prices, scenarios. Extended catalog: direct gain and active facades I. Extended catalog: Active facades II and problems. |
| M143 | Master's Degree in Aeronautical Engineering | 51430011 | Airport Planning, Design and Construction | Semester 2 | Part 1 of the course. Planning and factors determining design. TOPIC 1.- AIRPORT PLANNING. PRELIMINARY DATA. Aircraft characteristics that influence airport design. Consequences of the liberalization of air transport Competition between airports Hub configuration Multi-airport systems Promotion of destinations or Package tours or Low-cost airlines TOPIC 2.- STUDY OF DEMAND OVER TIME Introduction to demand forecasting Models for predicting demand Qualitative methods for demand forecasting Expert analysis Market analysis Quantitative methods for demand forecasting Data validation Extrapolation techniques Econometric models Competition models Practical principles for demand forecasting Demand forecasting in Spain TOPIC 3.- AIRSPACE AND AIR TRAFFIC CONTROL The role of air traffic control Services included in the air traffic service ATC services FIS services Controlled and uncontrolled airspace Aircraft separation criteria near the runway Separation between runways at airports Independent ILS approaches and PRMs Multiple independent approaches to Parallel runways ¿ Independent departures ¿ Departures and arrivals on staggered runways ¿ Independent arrivals on parallel or converging runways ¿ Dependent approaches ¿ Simultaneous non-aligned instrument approaches (SOIA) TOPIC 4.- DETERMINATION OF AIRPORT CAPACITY Basic definition of capacity Representations of movement area capacity ¿ Numerical summary values ¿ Pareto chart ¿ Capacity coverage diagrams ¿ Annual service volume Aerodrome capacity estimation methodologies ¿ Space-time analysis ¿ Queuing theory - Delays Simulation models TOPIC 5.- PLANNING. AIRPORT MASTER PLAN Planning philosophy The general plan of an airport Activities involved in the preparation of the general plan Limitations of the general plan Airport planning in Spain Airport planning instruments Legal framework The master plan ¿ General airport system ¿ Structure ¿ Preparation The special plan ¿ Objective and functions ¿ Processing and approval TOPIC 6.- LOCATION AND SITE. METEOROLOGY. Runway orientation Crosswind operations Analysis of coverage and prevailing winds with the wind rose Visibility and cloud ceiling Other meteorological factors TOPIC 7.- ENVIRONMENTAL FACTORS IN LOCATION The airport and its surroundings International standards and recommendations Spanish regulations Water quality problems Air quality problems The noise problem Noise metrics Aircraft classification according to noise Sources of noise in an aircraft ICAO balanced approach to noise reduction Part 2 of the subject. Design and Construction. TOPIC 1.- CONFIGURATION OF LAND AIRPORTS IN THEIR MANOEUVRING AREA Definitions Aerodrome classification Reference parameters and reduced runway length Runway dimensions Runway configuration and separation Runway strip and shoulder dimensions Runway end safety area (RESA), stop zones and obstacle free zones dimensions Anti-jet zone Taxiway dimensions Rapid exit roads Location of exit and access roads Taxiway overwidths Taxiway strips and shoulders Distance of taxiways to other infrastructures Dimensions of holding bays and taxiing holding points Apron sizing Parking typology Parking position sizing Engine test platform Apron service roads TOPIC 2 . OROGRAPHIC ENVIRONMENT Physical and radioelectric easements Obstacle limitation surfaces for landing runways Obstacle limitation surfaces for take-off runways Obstacles that do not violate limitation surfaces Obstacle markings and beaconing Typology of markings TOPIC 3. VISUAL AIDS FOR LANDING, TAKE-OFF AND TAXIING General Classification of visual aids Indicators and signaling devices Markings Runway center line markings Aim point marking Touchdown zone marking Runway side strip marking Taxiway center line marking side strip Runway holding point marking Intermediate holding point marking Aerodrome VOR checkpoint marking Aircraft stand and apron Apron safety lines Mandatory instruction markings Information markings Closed runway and taxiway markings Non-resistant surface markings Pre-threshold area markings Out-of-service area beacons Signs Identification sign Aerodrome Vehicle track holding position sign Beacons Lights or beacons Emergency lights Aeronautical beacons, aerobeacons and identification beacons Approach lighting systems Visual system maintenance Visual approach slope indicator systems Obstacle protective surfaces for visual approach systems Threshold identification lights Runway centre line lights Runway edge lights Runway threshold and wing bar lights Runway end lights Touchdown area lights Stop area lights line lights Taxiway edge lights Stop bar lights Crossing bar lights Intermediate holding position lights Apron exit anti-icing or de-icing lights Apron lighting Runway protection lights Visual docking and manoeuvring guidelines TOPIC 4. EARTHWORKS General Geotechnics of the site Foundation of masonry works Stages of earthworks Preparation of the site Cuttings and fills Measurement of earthworks Execution of earthworks Verification of execution TOPIC 5. TYPOLOGY OF ROADS AND PAVEMENTS General Conventional road surfaces Reinforced concrete pavement Prestressed concrete pavement Micro-reinforced cement concrete pavements with fibers Compacted dry concrete Reinforced asphalt mixtures Sandwich or inverted road surfaces Porous concrete and bituminous mixtures Tarred mixtures Aircraft braking surfaces (EMAS) Wire mesh runways TOPIC 6. GRANULAR AND STABILIZED MATERIALS IN BASES AND SUBBASES General Natural granular materials Granular materials from crushing Ground treatments Soil-cement and gravel-cement Compacted concrete Gravity treatment with hydrocarbonate binders Gravel-bitumen TOPIC 7. ROADS WITH ASPHALT AGGLOMERATES AND HYDRAULIC CONCRETE PAVEMENTS General Hydrocarbonate binders Bituminous agglomerates Agglomerate dosage and design bituminous Laying of bituminous agglomerate Cements Aggregates Water Dosage Joints in concrete Manufacture and laying of concrete Laying of work TOPIC 8. CALCULATION OF PAVEMENTS AND PAVEMENTS. ACN/PCN NOTIFICATION Generalities Calculation of pavements with flexible pavements Drainage of the pavement Calculation of pavements with concrete pavements Notification of pavement strength ACN/PCN TOPIC 9. MAINTENANCE, REHABILITATION AND REINFORCEMENT OF PAVEMENTS Inspection and maintenance of movement areas Inspection of pavements and pavements Recognition and auscultation of pavements Surface regularity of pavements Coefficient of friction of the surface of the movement area Measurement of the coefficient of friction Information on the condition of the surface Cleaning of rubber from tires and spills Regrowth of pavements. Maintenance and reinforcement TOPIC 10. NON-CONVENTIONAL AIRPORTS Generalities Short-runway airports Hydro-airports Heliports Heliports: Easements and visual aids |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210043 | Energy Efficiency in Thermal Installations in Buildings | Semester 1 | 1. Introduction 2. Basic design in air conditioning 3. Energy Structure 4. Savings in air conditioning 5. Consumption calculation tools 6. Energy analysis 7. Efficient design in air conditioning |
| 225 | Degree in Civil Engineering | 2250015 | Hydraulics and Hydrology | Semester 2 | Hydrostatics Hydrodynamics Hydraulics of pressure pipelines Hydraulics of open pipelines Elements of surface and underground hydrology |
| 225 | Degree in Civil Engineering | 2250072 | Hydrology Supplements (CC, TS) | Semester 1 | Topic 1: Hydrology. Phases of the hydrologic cycle. Precipitation. Precipitation losses. Rainfall-runoff transformation. Unit hydrograph. Rational method. Synthetic hydrographs. Flow propagation. Topic 2: Hydraulic Calculations Movement in pipes: flow in circular conduits, coefficient of friction, practical calculation of pipes, wave propagation in pipes. Movement in channels: uniform, gradually varied, and rapidly varied flow. Unsteady flow: dam bursting waves. Topic 3: Introduction to River Engineering . Notions of river hydraulics. Types and sizing of channeling. Bridge hydraulics. Topic 4: Channels . General concepts. Layout and typical section. Types, description, and construction aspects of linings. Special works. Topic 5: Pressure pipes . Generalities. Ductile iron pipes. Steel pipes. Reinforced and prestressed concrete pipes. PVC pipes. PE pipes. GRP pipes. Others. Valves and fittings. Pipe installation. Mechanical pipe calculations. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210078 | Transportation Engineering | Semester 2 | THEMATIC BLOCK I: TRANSPORT NETWORKS Topic 1. The transport problem and basic foundations Topic 2. The assignment problem Topic 3. Networks and graphs Topic 4. Maximum flow in a network Topic 5. Minimum route in a network Topic 6. Flow with minimum cost in a network Topic 7. Flow with minimum cost and multiple goods Topic 8. Assignment and non-linear networks Topic 9. Methods for solving transport problems and large networks: restricted methods Topic 10. Accessibility and location Topic 11. Traffic flow and capacity THEMATIC BLOCK II: TRANSPORT MODELS AND TECHNIQUES Topic 12. Distance models Topic 13. Vehicle routing problems Topic 14. Queue analysis THEMATIC BLOCK III: INDUSTRIAL HANDLING SYSTEMS Topic 15. Handling systems THEMATIC BLOCK IV: INTERMODALITY Topic 16. Intermodality in transport |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210135 | Perception in Automatics and Robotics | Semester 2 | 1 Inspection: texture analysis 2 Detection and monitoring: motion, Kalman filter 3 Quality control: K-means, k-distance classifier, RN 4 Localization, mapping: position estimation, environment representation, map creation. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210125 | Materials Engineering | Semester 2 | BLOCK I: INTRODUCTION TO MATERIALS ENGINEERING Topic 1: Metallic Materials Topic 2: Ceramic Materials Topic 3: Polymeric Materials Topic 4: Composite Materials BLOCK II: MECHANICAL CHARACTERIZATION OF MATERIALS Topic 5.- Introduction to the characterization of materials Topic 6.- Characterization of metallic materials Topic 7.- Characterization of fiber-reinforced composite materials Topic 8.- Characterization of adhesives BLOCK III. POWDER METALLURGY Topic 9: Introduction and manufacture of powders. Topic 10: Powder metallurgical routes. Topic 11: Products and applications BLOCK IV: MAGNETIC MATERIALS Topic 12. Types of magnetic materials Topic 13. Hysteresis curve Topic 14. Hard magnetic materials Topic 15. Soft magnetic materials Topic 16. Market and potential applications BLOCK V: ENVIRONMENTAL DEGRADATION AND PROTECTION Topic 17: Oxidation and corrosion Topic 18: Corrosion prevention methods Topic 19. Wear Topic 20. Coatings Topic 21: Environmental degradation of ceramics and polymers BLOCK VI: MATERIALS SELECTION Topic 22. Industrial design Topic 23. Selection by the Asbhy method (I) Topic 24. Selection by the Asbhy method (II) |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560039 | Industry and Environment | Semester 2 | Classification and characterization of sources of environmental impact in industry. Environmental policies and sustainability. Tools for addressing environmental challenges in industry. Climate change analysis (mitigation and adaptation). Sustainable Development Goals and Industry. |
| 197 | Degree in Aerospace Engineering | 1970011 | Physics Extension | Semester 1 | Kinematics and vector dynamics of points, particle systems, and rigid bodies. Analytical mechanics. Impulsive dynamics. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600006 | Micro and Nano Electronics | Semester 2 | 1. Electronic simulation with CADENCE. 2. Hardware description languages for analog circuits. 3. Basic block design. 4. Electronic system design. 5. Analog circuits in aerospace applications. |
| M164 | Master's Degree in Electrical Energy Systems | 51640007 | Electrical Network Analysis Laboratory | Semester 2 | Laboratory Block 1: Static Analysis o Static analysis of an electrical power system o Network elements model: o Input file: *.raw o Fault detection in models o Load distribution o Analysis of the state of an electrical power system o Safety analysis of an electrical power system o Short circuit analysis of an electrical power system o Network elements model: o Input file: *.seq o Short circuit analysis instructions o Analysis of output files o OPF Block 2: Dynamic Analysis o Introduction to the dynamics of electrical power systems o Synchronous machine model: AVR, PSS, power/frequency regulator o Transient stability o Frequency stability |
| M164 | Master's Degree in Electrical Energy Systems | 51640013 | Digital Measurement and Protection Systems for Electrical Systems | Semester 1 | Introduction to electrical measurements Basic mathematical treatment in Digital Signal Processing Discrete transforms Simulation tools Moving window treatment Harmonic calculation Fast algorithms for DFT Application to digital protections Introduction to wavelet transforms |
| M181 | Master's Degree in Chemical Engineering | 51810002 | Biorefineries | Semester 1 | The course is divided into four main sections that cover the following topics: - Fundamentals of Biorefineries: concepts, types, and platforms - Fundamentals of biomass transformation processes - Production of biofuels, biofuels, and bioproducts - Energy, economic, and environmental analysis of biorefineries. The first section develops the fundamental concepts of biorefineries, their classification and typology, the main processes that comprise them, experiences to date in Spain and around the world, etc. Likewise, the biomass resource, logistics, and the biomass market are studied. The second section studies biomass transformation processes, including physical and chemical pretreatment processes as well as thermochemical, biochemical, and hydrothermal conversion processes. The third section describes the production processes of biofuels (biofuels and chemicals) and bioproducts. Finally, the fourth section presents a detailed analysis of the different types of biorefineries, grouped into two large "families." thermochemical and biochemical, the different platforms that define the various biorefineries currently under development (lipids, sugars, biogas, proteins, synthesis gas, etc.) as well as an analysis of the energy and environmental efficiency of biorefineries. |
| 199 | Degree in Telecommunications Technology Engineering | 1990054 | Electronic Instrumentation | Semester 1 | Electronic Instrumentation. Measurement Systems. Interference Problem Analysis. Electromagnetic Compatibility |
| 199 | Degree in Telecommunications Technology Engineering | 1990002 | Computers fundamentals | Semester 1 | Basic computer architecture. Low-level microprocessor programming. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900002 | Advanced structure analysis | Semester 2 | 1. Nonlinear analysis. Geometric nonlinearity. Instability 1.1. Introduction 1.2. Simple elements subjected to compression 1.3. Beam-column 1.4. Stiffness matrix considering second-order effects. Resolution methods 1.5. Global buckling of structures 1.6. Buckling factor 1.7. Cables 1.8. Practical aspects 2. Nonlinear analysis. Materials with nonlinear behavior 2.1. Introduction 2.2. Inelastic behavior of materials. Hardening models 2.3. Plasticity in bars 3. Evolutionary construction modeling 3.1. Introduction 3.2. Nonlinear behavior due to variable elements 3.3. Application 4. Dynamic analysis. Time domain and frequency domain methodologies 4.1. Introduction 4.2. Summary of modal superposition and spectral analysis methods 4.3. Transient analysis (linear and nonlinear) 4.4. Dynamic loads 4.5. Frequency response function 4.6. Model updating 4.7. Practical applications: footbridges, moving loads (resonance and cancellation velocities), etc. 4.8. Earthquake: response spectra and accelerograms. 5. Nonlinear seismic analysis 5.1. Design based on seismic performance 5.2. Simplified method of nonlinear static analysis 5.3. Capacity and demand curves 5.4. Estimation of the maximum seismic response 6. Wave propagation 6.1. Introduction 6.2. Wave propagation in the ground 6.3. The vibration problem caused by traffic. Regulations. 6.4. Types of analysis 6.5. Practical applications |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920034 | Dynamics of Multibody Systems | Semester 2 | The course consists of two thematic blocks: - Computational Kinematics - Computational Dynamics The first block, Computational Kinematics, shows the machine modeling techniques for simulation, including the selection of coordinates and reference systems and the kinematic restrictions to which they are subject. Based on the model, the computational techniques for analyzing position, velocity and acceleration that allow kinematic simulation are shown. The second block, Computational Dynamics, shows the automatic formulation and calculation of the equations of motion of multibody systems in their ODE and DAE forms. The block continues by showing the numerical methods for solving these equations in the time domain that allow the dynamic simulation of machines. |
| 203 | Degree in Industrial Technology Engineering | 2030030 | Basic Operations with Solids and Fluids | TO | TOPIC 1.- PROPERTIES OF GRANULATED SOLIDS TOPIC 2.- STORAGE AND TRANSPORT OF SOLIDS TOPIC 3.- SIEVING TOPIC 4.- SIZE REDUCTION TOPIC 5.- CIRCULATION OF FLUIDS IN DUCTS TOPIC 6.- IMPULSION OF LIQUIDS TOPIC 7.- IMPULSION OF GASES TOPIC 8.- AGITATION TOPIC 9.- MOVEMENT OF PARTICLES WITHIN FLUIDS TOPIC 10.- CLASSIFICATION AND SEPARATION OF SOLIDS TOPIC 11.- CIRCULATION OF FLUIDS THROUGH POROUS MEDIA TOPIC 12.- FILTRATION TOPIC 13.- FLUID DYNAMIC DESIGN OF PACKED TOWERS TOPIC 14.- FLUIDIFICATION |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950010 | Engineering and Supervision of Chemical Plants | Semester 2 | Block I: Engineering project in a chemical plant Introduction to design. Strategies Organization and planning of a project Project planning and design software Documentation and drawings Permitting Industrial legalization Purchase management Block II: Regulations and regulations Storage of chemical products - Fuels Pressure equipment - Boilers Industrial insulation Legionella control and maintenance of cooling towers Fluid propulsion and solid transport equipment Industrial safety and hygiene Block III: Equipment and instrumentation design Boilers. Boiler water conditioning. Propulsion equipment Exchangers Cooling towers Absorption columns Storage tanks Instrumentation Valves Connections. Flanges. Fittings Block IV: Layout of a chemical plant Equipment implementation Piping Support Equipment assembly Block V: Supervision and analysis of chemical processes Estimation of investment and operation costs Data acquisition systems Industrial process control systems Start-up, operation and shutdown manuals Safety plans. Emergency response |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940037 | Micro and Nano Electronics | Semester 2 | 1. Electronic simulation with CADENCE. 2. Hardware description languages for analog circuits. 3. Basic block design. 4. Electronic system design. 5. Analog circuits in aerospace applications. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210055 | Electronic Power Conversion Systems | Semester 1 | Power electronics devices and components. Converters: topologies, circuits, and control techniques. Applications for energy conversion. |
| 199 | Degree in Telecommunications Technology Engineering | 1990006 | Statistics | Semester 2 | Statistical methods, stochastic processes and applications in Telecommunications Engineering. |
| 199 | Degree in Telecommunications Technology Engineering | 1990071 | Industrial Automation and Communications | Semester 2 | - Introduction to automation. - Modeling and simulation of discrete event systems. - Programmable logic controllers. - Fieldbuses |
| 199 | Degree in Telecommunications Technology Engineering | 1990029 | Digital Multimedia Signal Processing | Semester 1 | Algorithmic techniques for digital signal processing. Applications to audio and image processing. |
| 197 | Degree in Aerospace Engineering | 1970061 | Navigation Aid Systems | Semester 1 | Radar. Air Navigation Aid Systems, air traffic control infrastructure. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040002 | Optical Communications | Semester 1 | BLOCK 1: Optical signal propagation BLOCK 2: Optical signal generation BLOCK 3: Optical signal detection BLOCK 4: Optical Networks |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560017 | Numerical methods | Semester 2 | Introduction to numerical calculus. Solving systems of linear equations. Solving nonlinear and linear equations. Optimization. Interpolation. Numerical quadrature and differentiation. Numerical methods for ordinary differential equations. Numerical methods for partial differential equations. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270005 | Chemistry | Semester 1 | The subject will consist of three thematic blocks, which will be those detailed below BLOCK I. Basic concepts of Chemistry: stoichiometry and states of matter BLOCK II. Chemical change: Kinetics, Thermodynamics, Equilibrium BLOCK III. Equilibria in aqueous solutions. |
| 197 | Degree in Aerospace Engineering | 1970015 | Thermodynamics | Semester 1 | S01 Initial Concepts S02 Partial Molar Magnitudes S03 Principles of Thermodynamics; Exergy S04 Formulation of the Thermodynamic Equations of State S05 Thermodynamic Potentials S06 Equilibrium and Stability S07 Deduction of the Thermodynamic Equations of State S08 Chemical Reactions S09 Combustion S10 Gas Power Cycles S11 Conduction S12 Convection S13 Radiation S14 Combined Mechanisms |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210048 | Solar Energy in Buildings | Semester 1 | BLOCK I. Active solar systems. Topic 1. Solar radiation. Topic 2. Semi-transparent media. Topic 3. Flat solar collector. Topic 4. Thermal storage systems. Topic 5. Solar thermal energy systems. Topic 6. Design methods. Topic 7. Regulations. BLOCK II. Passive solar systems. Topic 8. Direct solar gain. Topic 9. Indirect solar gain: Trombe and parietodynamic walls. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990006 | Environmental Management in Industry | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990019 | Circular Economy and Sustainability | Semester 1 | Course Program Topic 1. Concepts of Sustainability and Circular Economy Topic 2. Sustainability and Environmental Management PRACTICAL CASE No. 1: Technical bases for the implementation of an integrated urban sustainable development process: the Local Agenda 21. Sustainability diagnosis, indicator system and action plan. Topic 3. Environmental Management Systems Topic 4. Economy and Environment PRACTICAL CASE No. 2: Strategy for plastics in a circular economy Topic 5. Circular Economy and Solid Waste PRACTICAL CASE No. 3: Advanced Landfill Mining (Enhanced Landfill Mining). STUDENT SEMINAR No. 1 Topic 6. Ecodesign and Ecolabel Topic 7. Quantification of Sustainability STUDENT SEMINAR No. 2 PRACTICAL CASE No. 4: The circular economy in the fertilizer production. European Commission Regulations CASE STUDY NO. 5: Critical Raw Materials and the Circular Economy (EU) CASE STUDY NO. 6: Implementation of the Deposit, Return and Refund System (DRRS) in the city of Seville/Andalusia/Spain. Combined example of circular economy and sustainability. STUDENT SEMINAR NO. 3 STUDENT SEMINAR NO. 4 STUDENT SEMINAR NO. 5 STUDENT SEMINAR NO. 6 NOTE: Throughout the course, an additional lecture given by a guest lecturer may be offered. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210100 | Advanced Production Systems (OGSP) | Semester 1 | Cellular manufacturing and sustainable manufacturing. Intelligent production planning, scheduling, and control systems. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210063 | Nuclear Technology | Semester 2 | Thematic sections: -Nuclear reactions -Nuclear reactor physics protection -Radiation waste treatment |
| 225 | Degree in Civil Engineering | 2250044 | Road infrastructure | Semester 1 | BLOCK I Topic 1. INTRODUCTION Topic 2. LAYOUT: CONDITIONS, PROCESS AND COMPUTERIZATION. Topic 3. EARTHWORKS. Topic 4. ROCK EXCAVATION WITH BLASTING Topic 5. SLOPE STABILIZATION Topic 6. PLATFORM DRAINAGE Topic 7. ROAD STRUCTURES AND TUNNELS BLOCK II Topic 8. LOANS, GRAVEL PITS AND QUARRIES. OBTAINING AGGREGATES. Topic 9. FORMATION OF THE ESPLADE AND FOUNDATION OF THE ROAD PAVEMENT. Topic 10. CONSTITUTION OF ROAD PAVEMENTS. Topic 11. GRANULAR LAYERS. Topic 12. LAYERS TREATED WITH HYDRAULIC BLOCKERS BLOCK III Topic 13. BITUMINOUS BINDERS. Topic 14. IRRIGATION AND SURFACE TREATMENTS Topic 15. BITUMINOUS MIXES. MATERIALS, CHARACTERISTICS AND TYPES. Topic 16. BITUMINOUS MIXES FOR LOWER ROAD LAYERS Topic 17. BITUMINOUS MIXES FOR WEARING LAYERS Topic 18. MANUFACTURE AND INSTALLATION OF BITUMINOUS MIXES Topic 19. CONCRETE PAVEMENTS BLOCK IV Topic 20. SURFACE CHARACTERISTICS OF PAVEMENTS. Topic 21. SIZING OF ROAD FACILITIES. Topic 22. ROAD FACILITATION. BLOCK V Topic 23. HORIZONTAL AND VERTICAL SIGNALLING, BEACONING AND DEFENSES. Topic 24. AUXILIARY FACILITIES. Topic 25. INTEGRAL ROAD MANAGEMENT AND MAINTENANCE SYSTEMS Topic 26. PAVEMENTS IN SPECIAL AREAS BLOCK VI Topic 27. ROAD SAFETY ANALYSIS Topic 28. SAFETY IMPROVEMENT IN ROAD INFRASTRUCTURES BASIC BIBLIOGRAPHY .- ¿Road engineering Volume II¿. C. Kraemer, J. Mª Portillo, S. Rocci, MG Romana, V. Sanchez Blanco and MA del Val. .- ¿General Technical Specifications for Road and Bridge Works¿, PG3 and PG-4. Ministry of Public Works. .- Standard 3.1 IC ¿Layout¿ Road instructions. Ministry of Public Works. .- ¿Instruction 5.2 IC ¿Surface drainage¿. Ministry of Public Works. .- ¿Recommendations for the design and construction of underground drainage in road works¿. OC 17/2003. Ministry of Public Works. .- Standard 6.1 IC ¿Road sections¿. Ministry of Public Works. .- Standard 6.3 IC ¿Road rehabilitation¿. Ministry of Public Works. .-¿Instructions for the design of road surfaces for the Andalusian Road Network¿. ICAFIR. Regional Government of Andalusia. .- Standard 8.1 IC ¿Vertical signage¿. Ministry of Public Works .- Standard 8.2 IC ¿Road markings¿. Ministry of Public Works. .- Standard 8.3 IC ¿Signage of works¿. Ministry of Public Works. .- OC 35/2014 ¿Criteria for the application of vehicle containment systems¿. .- ¿Bituminous slurries and cold microagglomerates¿. Asefma (Spanish Association of Asphalt Mixture Manufacturers) .- ¿Test methods for hot bituminous mixtures¿. Asefma (Spanish Association of Asphalt Mixture Manufacturers) .- ¿Collection of monographs on asphalt mixtures¿. Asefma (Spanish Association of Asphalt Mixture Manufacturers) .- ¿Rock drilling and blasting manual¿. Geominero Technological Institute of Spain. .- ¿Aggregates manual¿. ETS Mining Engineers of Madrid. .- ¿Procedures for the study, design and management of road safety measures in infrastructures¿. J. Mª Pardillo. |
| 225 | Degree in Civil Engineering | 2250031 | Railways | Semester 2 | GENERALITIES. Topic 1. Introduction to railways. THEMATIC BLOCK I: INFRASTRUCTURE TECHNOLOGY. Topic 2. Rails. Topic 3. Track parameters. Topic 4. Sleepers. Topic 5. Fastenings. Topic 6. Ballast. Topic 7. Slab track. Topic 8. Platform. Topic 9. Origin and evaluation of stresses. Topic 10. Mechanical behavior of the track. Topic 11. Dimensioning of the track and its elements. Topic 12. Beams and special tracks. Topic 13. Special equipment. Topic 14. Electrification. THEMATIC BLOCK II: RAILWAY DYNAMICS. Topic 15. Dynamics of mechanical systems. Deterministic stresses. Topic 16. Dynamics of mechanical systems. Stochastic stresses. Topic 17. Track irregularities. Topic 18. Wheel-rail contact. Topic 19. Rolling stock modeling. Topic 20. Global dynamics of railway vehicles. Topic 21. Vehicle-track interaction. THEMATIC BLOCK III: ROLLING STOCK TECHNOLOGY. Topic 22. Basic elements of rolling stock. Topic 23. Structure. Topic 24. Resistance, stresses and traction. Topic 25. Braking. Topic 26. Traction and collision devices. Topic 27. Special technologies. Topic 28. Metropolitan railways. Topic 29. Automated transport. THEMATIC BLOCK IV: HIGH-SPEED TECHNOLOGY. Topic 30. Infrastructure. Topic 31. Motive material. Topic 32. Structure. Topic 33. Magnetic levitation trains. Topic 34. Other technologies. BASIC BIBLIOGRAPHY GARG, VK DYNAMICS OF RAILWAY VEHICLE SYSTEMS .Canada: Academic Press (1984). OLIVEROS, F.; LOPEZ PITA, A.; MEGIA PUENTE, MJ RAILWAY TREATY I. VIA. Madrid: Rueda (1977). HAY, WW RAILROAD ENGINEERING .USA : John Wiley & Sons (1982). NEWLAND, FROM RANDOM VIBRATIONS AND SPECTRAL ANALYSIS. USA: Longman (1984). ANDREWS, HI RAILWAY TRACTION. THE PRINCIPLES OF MECHANICAL AND ELECTRI¬CAL RAILWAY TRACTION.Netherlands: Elsevier Science Publishers (1986). PAZ, M. STRUCTURAL DYNAMICS. THEORY AND COMPUTATION. USA: Van Nostrand Reinhold Co. (1980). |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210056 | Numerical and Experimental Stress Analysis (IRM) | Semester 1 | Preprocessing of finite element models using CAD tools. Numerical modeling methods. Fundamentals and applications. Experimental techniques for measuring displacements, deformations, and stresses. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210015 | Metallic Structures (DECI) | Semester 2 | Materials, durability. Ultimate limit states of steel structures. Serviceability limit states of steel structures. Modeling of steel structures, considering imperfections. Design and calculation of steel structures. Design of steel structures against fire. Connections and structural elements. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270048 | Optimization Methods | Semester 1 | Multicriteria optimization. Nonlinear optimization. Optimization methods with data uncertainty. Application to modeling and problem solving in organizational engineering. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210111 | Hydraulic machines | Semester 1 | Fluid dynamics around solid bodies. Introduction to hydraulic systems. Characterization of hydraulic machines. Pressure, level, and flow measurement in hydraulic systems. Calculation of hydraulic and pneumatic systems. Compressibility effects in pipeline networks. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270021 | Quality Management | Semester 1 | TOPIC I. QUALITY: FUNDAMENTALS AND VOCABULARY - Terms and definitions according to UNE EN ISO 9000 - Actual quality and perceived quality. - Costs of conformity and non-conformity. Total cost optimum environment. - Introduction to quality infrastructure TOPIC II. INTRODUCTION TO MANAGEMENT SYSTEMS (MS) - Quality management principles according to UNE EN ISO 9000 - Quality management systems approach, process-based quality management system model, continuous improvement objective and relationship with excellence models. TOPIC III. QUALITY MANAGEMENT SYSTEM. - Quality management system requirements according to UNE EN ISO 9001. - Guidelines for the documentation of quality management systems UNE 66925. - Guidelines for quality plans UNE ISO 10005. TOPIC IV. GUIDES AND DIRECTIVES FOR DEVELOPING THE QUALITY MANAGEMENT SYSTEM. - Guide for the management of the continuous improvement process UNE 66178. - Guide for the implementation of indicator systems UNE 66175. - Guidelines for the audit of management systems UNE EN ISO 19011. - Guidelines for the measurement, monitoring and analysis of customer satisfaction UNE 66176. - Guidelines for the handling of complaints in organizations UNE ISO 10002. - Guidance on the use of statistical techniques in the quality management system 9001. UNE ISO 10017. TOPIC V. INTRODUCTION TO ENVIRONMENTAL MANAGEMENT SYSTEMS. - Environmental management system UNE EN ISO 14001. Morphology of the environmental management system. Identification and evaluation of environmental aspects. TOPIC VI. INTRODUCTION TO QUALITY MANAGEMENT SYSTEMS IN SERVICES - The SERVQUAL method. - Quality management system in small businesses UNE 175001-1. TOPIC VII. INTRODUCTION TO SYSTEMS INTEGRATION - Management for the sustained success of an organization UNE EN ISO 9004. - Guidelines on management system standards UNE 66172. - Guide for the integration of management systems UNE 66177. - Introduction to business excellence models: Japanese model (Deming), American model (Malcolm Baldrige) and European model (European Foundation for Quality Management). - Guidelines for obtaining financial and economic benefits UNE ISO 10014. |
| M143 | Master's Degree in Aeronautical Engineering | 51430050 | Aeronautical Structures Complements | Semester 2 | 1. Introduction to aircraft structures 1.1. Introduction to aircraft structures 1.2. Introduction to the design of aircraft structures 1.3. Introduction to structural design standards 1.4. Introduction to load determination 2. Analysis of thin-walled monocoque structures. Extension to complex and three-dimensional sections. 2.1. Review of elementary theory. Hypotheses. Notation. Simplifications. 2.2. Bending. 2.3. General relationships between stresses, strains and displacements. 2.4. Equilibrium equations. Twist and warping of sections. 2.5. Torsion in open, closed, single-cell and multi-cell tubes. 2.6. Shear in open tubes. Shear center. 2.7. Shear in closed, single-cell and multi-cell tubes. 2.8. Displacement calculation. Gyration. 3. Analysis of semi-monocoque structures. Extension to complex three-dimensional sections. 3.1. Structural idealization. Effective width of sheet metal panels. 3.2. Effect of idealization on the analysis of open and closed tubes. 3.3. Displacement calculation. 4. Structural instability analysis and application to idealized semi-monocoque structures . 4.1. Review of Euler and beam-column theory . 4.2. Instability of stringers . 4.3. Panel instability. 4.4. Stiffened panel problem. 5. Introduction to dynamic structural calculation. 5.1. The structure as a system of N degrees of freedom . 5.2. Equations and matrices of the straight bar . 5.3. Mass matrices. 5.4. Structural equations. 5.5. Solution to the problem . 5.6. Spectral loads . 6. Introduction to the design of aeronautical structures with composite material. 7. Calculation of joints in aeronautical structures 8. Fatigue and damage tolerance in aeronautical structures |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550002 | Biomechanics | Semester 1 | Block 1. Introduction Block 2. Kinematics and kinetics of the musculoskeletal system Block 3. Tissue behavior models |
| 197 | Degree in Aerospace Engineering | 1970045 | Electronic Technology | Semester 2 | Programmable logic devices and microprocessors |
| 199 | Degree in Telecommunications Technology Engineering | 1990087 | Sensor Networks and Autonomous Systems | Semester 2 | Sensor Networks: Information Routing and Distribution. Communications in Autonomous Systems. |
| M181 | Master's Degree in Chemical Engineering | 51810008 | Environmental Management in Industry | Semester 2 | Environmental impact studies. Environmental assessments of plans and programs. Integrated environmental authorization. Audits of environmental management systems. Environmental inspections. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920038 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M190 | Master's Degree in Civil Engineering (2019) | 51900005 | Hydrology Complements | Semester 1 | Topic 1: Hydrology. Phases of the hydrologic cycle. Precipitation. Precipitation losses. Rainfall-runoff transformation. Unit hydrograph. Rational method. Synthetic hydrographs. Flow propagation. Topic 2: Hydraulic Calculations Movement in pipes: flow in circular conduits, coefficient of friction, practical calculation of pipes, wave propagation in pipes. Movement in channels: uniform, gradually varied, and rapidly varied flow. Unsteady flow: dam bursting waves. Topic 3: Introduction to River Engineering . Notions of river hydraulics. Types and sizing of channeling. Bridge hydraulics. Topic 4: Channels . General concepts. Layout and typical section. Types, description, and construction aspects of linings. Special works. Topic 5: Pressure pipes . Generalities. Ductile iron pipes. Steel pipes. Reinforced and prestressed concrete pipes. PVC pipes. PE pipes. GRP pipes. Others. Valves and fittings. Pipe installation. Mechanical pipe calculations. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930046 | Environmental Systems | Semester 2 | Block I. Ecosystems and natural resources. Block II. Ecological systems: disturbances and pollution. Block III. Alteration of ecological factors. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940033 | Industrial communications | Semester 1 | Thematic Blocks: Block 1. Signal Modulation in Communications. Block 2. Guided and Unguided Signal Propagation. Block 3. Fundamentals of Optical Communications. Block 4. Industrial Buses and Optical Sensor Networks. Block 5. Topologies and Links Used in Industrial Communication Networks. Block 6. Industrial Communication Networks. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930042 | Noise Pollution Engineering and Control | Semester 2 | Topic 1: Basic acoustic concepts: definitions, assessment quantities, the audition process, frequency analysis, etc. Topic 2: Acoustic indices: noise assessment units, acoustic assessment indices Topic 3: Limits and regulations for environmental noise management. International analysis and national analysis (national requirements, regional requirements and local requirements) Topic 4: Control by absorption. Acoustic absorption and reverberation time. Topic 5: Sound radiation through the air. Engineering method for predicting sound levels in open and closed spaces. Topic 6: Noise control through shielding. Design and calculations of acoustic screens Topic 7: Acoustic insulation against airborne noise and structure-borne noise: soundproofing and acoustic encapsulation. Topic 8: Noise control using silencers. Silencers for rooms, silencers for fans and other HVAC equipment, silencers for motors and compressors, silencers for valves and ejectors. Topic 9: Strategic Noise Maps and Action Plans. Road noise maps, railway line noise maps, airport noise footprints, port noise maps, and urban agglomeration noise maps. International standards for assessing the emissions of mobile noise sources (road traffic, rail traffic, and air traffic). European Union requirements and trends in other countries in the assessment of environmental noise pollution and action plans aimed at reducing it. Topic 10: Environmental noise measurement methods. Noise measurement instrumentation and equipment. International reference standards. Importance of the method for assessing compliance with limits. Topic 11: Acoustic study of noise sources and activities. Methodology for justifying compliance with regulatory limits using noise prediction methods. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210080 | Engineering and Data Science applied to Sustainable Development (DIS) | Semester 1 | Techniques and tools for Data Engineering and Science: Data extraction, transformation, and loading; Data mining; Data visualization; Data science for strategic decision-making. |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950006 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210097 | Advanced Robotics (AR) | Semester 1 | Control techniques for robots. Autonomous robotic systems. |
| M228 | Master's Degree in Operation of Space Systems | 52280003 | Communications and Electronics for Aerospace Engineers | Semester 1 | Digital Signal Processing; Radio Frequency and Radio Propagation Systems; Electronic Communications Systems; Electronic Systems for Navigation. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970035 | AC/DC Devices and Systems | Semester 1 | Topic 1. Problem-solving techniques for transmission networks and conventional solutions. Topic 2. FACTS for transmission I: parallel connection. Topic 3. FACTS for transmission II: series and hybrid connection. Topic 4. Problem-solving techniques for distribution networks and conventional solutions. Topic 5. FACTS for distribution I: Voltage source converter. Topic 6. FACTS for distribution II: Applications. Topic 7. Other FACTS devices used in distribution. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970047 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 197 | Degree in Aerospace Engineering | 1970013 | Aerospace Materials Science and Technology | Semester 1 | - Structure-property relationships of metallic, polymeric, and ceramic materials. - Concepts related to diffusion, phase changes, equilibrium diagrams, and treatments. - Mechanical, optical, electrical, and magnetic properties. - Basics of behavior. - Aerospace material alloys. |
| 197 | Degree in Aerospace Engineering | 1970048 | Avionics and Navigation Aid Systems | Semester 1 | Aircraft electronic systems. Flight control computers. Navigation and landing aid systems. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920040 | Materials Engineering | Semester 2 | BLOCK I: INTRODUCTION TO MATERIALS ENGINEERING Topic 1: Metallic Materials Topic 2: Ceramic Materials Topic 3: Polymeric Materials Topic 4: Composite Materials BLOCK II: MECHANICAL CHARACTERIZATION OF MATERIALS Topic 5.- Introduction to the characterization of materials Topic 6.- Characterization of metallic materials Topic 7.- Characterization of fiber-reinforced composite materials Topic 8.- Characterization of adhesives BLOCK III. POWDER METALLURGY Topic 9: Introduction and manufacture of powders. Topic 10: Powder metallurgical routes. Topic 11: Products and applications BLOCK IV: MAGNETIC MATERIALS Topic 12. Types of magnetic materials Topic 13. Hysteresis curve Topic 14. Hard magnetic materials Topic 15. Soft magnetic materials Topic 16. Market and potential applications BLOCK V: ENVIRONMENTAL DEGRADATION AND PROTECTION Topic 17: Oxidation and corrosion Topic 18: Corrosion prevention methods Topic 19. Wear Topic 20. Coatings Topic 21: Environmental degradation of ceramics and polymers BLOCK VI: MATERIALS SELECTION Topic 22. Industrial design Topic 23. Selection by the Asbhy method (I) Topic 24. Selection by the Asbhy method (II) |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280036 | Automation of Production Systems | Semester 1 | CONTENT: Supervisory systems. Modeling and automation of production systems. Computer-aided manufacturing. Automation projects. THEMATIC BLOCKS: Contains the following thematic blocks: - Distributed supervisory and control systems - Modeling and simulation of production systems - Flexible manufacturing systems |
| 199 | Degree in Telecommunications Technology Engineering | 1990012 | Basic electronic | Semester 1 | Analog electronic circuits: amplifiers, feedback circuits. Logic families. Simulation tools. |
| 199 | Degree in Telecommunications Technology Engineering | 1990021 | Communications Circuits | Semester 1 | Radio frequency circuits. Electronic devices and circuits for transmission, routing, and terminals, both fixed and mobile. |
| 203 | Degree in Industrial Technology Engineering | 2030085 | Industrial Computing | Semester 1 | CONTENT: Real-Time Computer Systems. Industrial communications systems. THEMATIC BLOCKS: THEORY: Topic 1. Introduction to real-time systems Topic 2. Complements on computers, operating systems and languages Topic 3. Concurrency and timing services Topic 4: Synchronization services and communication through shared memory Topic 6: Communication through message passing and communications networks PRACTICES: 1) Class exercises 2) Laboratory practices on the content of the subject |
| 197 | Degree in Aerospace Engineering | 1970018 | Statistics and Operations Research | Semester 2 | Ability to apply knowledge of statistics and optimization. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210068 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210094 | Transportation and Distribution Networks (OGCS) | Semester 1 | BLOCK I: Flow in networks - The concept of graph - The flow model in networks - The minimum route problem - The maximum flow problem - The transport problem - Other flow models in networks BLOCK II: Transport and logistics networks - Location - Design of transport and distribution routes |
| 199 | Degree in Telecommunications Technology Engineering | 1990019 | Wave Propagation | Semester 2 | Basic concepts related to the mechanisms of propagation and transmission of electromagnetic and acoustic waves. Fundamentals of antennas. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900013 | Hydraulic Infrastructures | Semester 1 | Hydraulic regulation works Gates, spillways, weirs and drains Pressure pipes Canals Pumping stations Irrigation |
| 199 | Degree in Telecommunications Technology Engineering | 1990013 | Internet foundations | Semester 1 | Layered model. Link (HDLC), network, and transport layers. Routing and client/server architecture |
| M228 | Master's Degree in Operation of Space Systems | 52280007 | Orbital Dynamics | Semester 1 | Astrodynamics; orbits; orbital elements; propagation; basic mission analysis tools (ground tracks, coverage, visibility, eclipse calculation) |
| 199 | Degree in Telecommunications Technology Engineering | 1990076 | Mobile Application Design | Semester 2 | PART I: Knowledge of tools and procedures Topic 1: INTRODUCTION TO SOFTWARE MOBILE DEVICES Topic 2: MOBILE DEVELOPMENT IN ANDROID Topic 3: MOBILE DEVELOPMENT IN IOS PART II. Design and implementation of a mobile application. |
| 208 | Degree in Chemical Engineering | 2080022 | Heat Transmission | Semester 2 | Lesson 1. General concepts of heat transfer 1. Introduction. 2. General aspects of heat transfer mechanisms. 3. Thermodynamics and heat transfer. 4. Fields of application. 5. Basic heat transfer mechanisms: Conduction, convection and radiation. 6. Surface and volumetric balances. Lesson 2. Heat transfer mechanisms 1. Convection mechanism: Definition. Fourier's law. 2. Convection mechanism: Definition. Newton's law of cooling. 3. Radiation mechanism: Definition. Stefan-Boltzmann law. 4. Combined mechanisms. Identification of mechanisms. Controlling mechanisms 5. General methodology for problem solving. Lesson 3. Fundamentals of heat transfer by conduction. 1. Definition of the mechanism. 2. Thermal field: Fourier's law. 3. Vectorial character of the heat flux density. 4. Thermal conductivity. 5. Variation of conductivity with temperature. 6. Energy equation. Lesson 4. One-dimensional steady-state conduction I 1. General heat diffusion equation. 2. Particular cases of the general heat transfer equation. 3. Boundary conditions and uniqueness. 4. Imposed temperature, imposed flux, and convective boundary conditions. 5. Simultaneous multiple convection. 6. Boundary conditions in composite systems. Contact resistance. Lesson 5. One-dimensional steady-state conduction II 1. General steady-state heat transfer equation. Conditions of applicability 2. Elementary systems without generation: flat plate, infinite cylinder, sphere. 3. Thermal resistance and conductance 4. Composite systems without generation. Electrical analogy. Lesson 6. One-dimensional steady-state conduction III 1. Overall heat transfer coefficient. 2. Treatment of variable conductivity. 3. Systems with generation. 4. Basic methodology for solving conduction problems. Lesson 7. Heat transfer on extended surfaces 1. Introduction. Typology of extended surfaces and applications. 2. General fin equation. 3. Straight longitudinal fin of constant thickness: Approximate solution. 4. Fin efficiency. Heat flux on a finned surface. 5. Fin design. Lesson 8. Fundamentals of convective heat transfer 1. Introduction. Fundamental concepts. 2. Basic equations: Continuity, momentum, and energy. 3. Basic equations: Continuity, momentum, and energy. 4. Uniqueness conditions. 5. Particular equation of the mechanism: Newton's law of cooling. 6. Calculation of the convective heat transfer coefficient: Analytical, numerical, experimental, and analog methods. Lesson 9. Dimensionless Numerical Systems and Empirical Correlations in Convection I 1. Dimensionlessness of basic equations. 2. Dimensionless numbers. 3. Physical meaning of dimensionless numbers. Lesson 10. Dimensionless Numerical Systems and Empirical Correlations in Convection II 1. Experimental analysis of convection problems. Course effective: 2009/2010 2 of 4 2. Reference quantities. 3. Reference temperature difference. 4. Obtaining empirical correlations. Lesson 11. Dimensionless Numerical Systems and Empirical Correlations in Convection III 1. Generalization of results. 2. Limits of application. 3. Functional dependence of the Nusselt number on the type of fluid and flow conditions. Lesson 12. Viscous and Thermal Boundary Layer 1. Concept of viscous and thermal boundary layer. 2. Boundary layer considerations in heat transfer. 3. Boundary layer analogies in laminar flow. 4. Fundamental aspects of turbulent flow. Lesson 13. Forced convection in external flow I 1. Dimensionless numbers and reference quantities. 2. Local and mean film coefficients. 3. Correlations for flat plates in laminar and turbulent flow. 4. Correlations for cylinders and spheres in laminar and turbulent flow. 5. Correlations for tube banks. Lesson 14. Forced convection in internal flow I 1. Dimensionless numbers and reference quantities . 2. Inlet region and developed flow region. 3. Correlations for circular ducts in laminar and turbulent flow. 4. Correlations for ducts with non-circular cross-section. 5. Correlations for annular ducts. Lesson 15. Natural convection I 1. Dimensionless numbers and reference quantities. 2. Correlations for flat plates and vertical cylinders. 3. Correlations for horizontal and vertical flat plates. 4. Correlations for horizontal cylinders and spheres. 5. Correlations for internal flow. Lesson 16. Radiation. Definitions and laws. 1. Nature of radiation. Penetration depth. 2. The electromagnetic spectrum and thermal radiation. 3. Spectral and directional character of radiation. 4. Surface and volumetric exchanges. 5. Objectives of the study of radiation. Lesson 17. Definitions, laws and surface radiant properties I. 1. Intensity and luminance. 2. Steps for calculating radiant fluxes on a surface. 3. Emittance, irradiance and radiosity. Lesson 18. Definitions, laws and surface radiant properties II . 1. The blackbody. 2. Planck's and Wien's laws. 3. Stefan-Boltzmann law. Fraction of the emittance included in a band. 4. Behavior of real bodies with respect to radiation. Lesson 19. Definitions, laws and surface radiant properties III 1. Emissivity: spectral and directional character. 2. Absorptivity, reflectivity and transmissivity. 3. Gray body. 4. Gray bodies by bands. 5. Kirchoff's law Lesson 20. Radiant exchange between two surfaces and form factors. 1. Radiation leaving one surface and arriving at another. 2. Special case of diffuse irradiation. Form factor. 3. Reciprocity theorem. 4. Algebra of the form factor in closed spaces. 5. Evaluation using abacuses. 6. Hottel's method Lesson 21. Radiant exchange in gray and diffuse spaces without a participating medium. 1. General equations of radiant exchange in spaces with gray and diffuse surfaces. 2. Calculation of net heat fluxes. Matrix formulation. 3. Electrical analogy. 4. Special cases: black surfaces and radiating surfaces. 5. Methodology for solving uncoupled problems in total properties: Imposed temperature, imposed flux, and mixed case. Lesson 22: Solving coupled heat transfer problems. 1. General formulation of the combined mechanisms problem. 2. Identification of coupling variables. 3. Treatment of nonlinearities. 4. Use of equivalent temperatures. 5. Iterative procedures. 6. Bounding criteria. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320001 | Aeroelasticity | Semester 2 | 1. Introduction to Aeroelasticity 2. Static Aeroelasticity 3. Unsteady Potential Aerodynamics 4. Dynamic Aeroelasticity. Flutter at Small Angles of Attack 5. Gusts 6. Flapping and Separation Flutter 7. Experimental Aeroelasticity and Civil Aeroelasticity |
| 208 | Degree in Chemical Engineering | 2080042 | Industrial Process Automation | Semester 1 | Introduction to automation. Design and implementation of logic automation. Programmable logic controllers. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040013 | 5G and New Generation Radio Technologies | Semester 2 | HW Elements and Radio Tx and Rx Architecture. Radio Planning. Spectrum Management. Mobile Communication Systems. Satellite Communications. Radar. Radio Navigation and Positioning Systems. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320015 | Orbital Dynamics | Semester 1 | Astrodynamics; orbits; orbital elements; propagation; basic mission analysis tools (ground tracks, coverage, visibility, eclipse calculation) |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210042 | Cogeneration | Semester 1 | Verification report contents: Cogeneration systems based on steam turbines, gas turbines and reciprocating engines. Thermoeconomic analysis. Content structure L1 Energy context L2 Introduction to cogeneration L3 Regulatory framework L4 Cogeneration with steam turbine L5 Cogeneration with gas turbine and combined cycle L6 Cogeneration with reciprocating engines L7 Selection criteria and size of the cogeneration plant L8 Economic aspects and environmental impact management |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210051 | Steam Power Plants | Semester 1 | I. INTRODUCTION. II. THE BASIC STEAM TURBINE CYCLE: INFLUENCE OF THE MAIN CYCLE PARAMETERS ON CYCLE PERFORMANCE. III. MODIFICATIONS OF THE BASIC STEAM TURBINE CYCLE: INTERMEDIATE REHEAT CYCLE AND REGENERATIVE CYCLE. IV. COMBUSTION PRINCIPLES. V. STEAM GENERATORS. VI. STEAM TURBINES. VII. CONDENSERS. VIII. MONITORING AND TESTING. IX. REGULATION OF STEAM TURBINES. X. EMISSIONS FROM STEAM TURBINE PLANTS. |
| 225 | Degree in Civil Engineering | 2250040 | Health constructions | Semester 2 | Design, operation, and maintenance of water supply, sanitation, and sewage systems. The following subject areas are taught: CSA-1: WATER SUPPLY SYSTEMS ; CSA-2: SANITATION AND SEWAGE SYSTEMS ; CSA-3: PIPES AND TANKS |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270026 | Manufacturing Technologies | Semester 1 | Block 1: INTRODUCTION TO METROLOGY Block 2: CASTING PROCESSES Block 3: PARTICLE PROCESSES Block 4: POLYMER AND COMPOSITE MATERIALS PROCESSES Block 5: PLASTIC DEFORMATION FORMING PROCESSES Block 6: CHIP REMOVAL PROCESSES Block 7: JOINTS |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270029 | Human Factor of Organizations | Semester 2 | Organizational theory. Work organization models. Method and time studies. Incentive policy. Human team management. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560042 | Logistics | Semester 2 | Subject descriptors: - Introduction to Logistics. - Warehouse Management. - Supply Chain. - Distribution Routes. Block 0: Introduction to Logistics: This block, detailed in the teaching project, will introduce students to the field of logistics. The subject, its objectives and content, assessment system, etc. will be presented. Block 1: Supply Chain: This block addresses the general concepts of the supply chain and its relationship to logistics. Basic definitions and concepts will be presented, emphasizing relevant aspects. Process approaches to a supply chain will be presented. The aim is for students to acquire an understanding of how logistics costs are generated, classified, and managed, as well as the methodologies available for their analysis and allocation. Aspects of general interest such as international trade terms, among other aspects of the supply chain, will be included. Block 2: Warehouse Management: This block addresses the general concepts and functions of the warehouse. Typical warehouse activities are described, including receiving, putaway, picking, sorting, and shipping, as well as other related activities. Storage principles, warehouse layout and use, product flow diagrams, and warehouse space types are studied. In addition, unit loads and inventory profiles are addressed, as well as warehouse zones, movements, and types. Decisions and technologies related to the tactical organization of order picking and operational policies, or decision elements based on components of the warehousing system, are discussed. Aspects of connectors with distribution routes, such as plant and outdoor area design, cross-docking, and other aspects related to network flow, will be presented. Block 3: Transportation and Distribution Routes: This block focuses on transportation aspects related to unit loads and the processes involved. Concepts associated with the components of transportation logistics systems, including reverse logistics, are presented, and transportation location and costs are analyzed. The choice of transportation model and intermodal transportation are explored. The typologies of route planning problems and specific considerations are also addressed, among other aspects. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560005 | Physics I | Semester 1 | Mechanics, oscillations and waves. |
| M146 | Master's Degree in Industrial Engineering | 51460082 | Electronic Systems for Renewable Energy Management | Semester 2 | Chapter I. Introduction to electronic systems for renewable energy management Chapter II. Wind energy Chapter III. Photovoltaic energy Chapter IV. FACTS systems, energy storage and electric vehicles |
| 197 | Degree in Aerospace Engineering | 1970050 | Airport Structures II | Semester 1 | Calculation, design, and typology of airport buildings and equipment. Prefabricated and prestressed structural elements. Unique elements of airport buildings. Development of structural projects. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550007 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M165 | Master's Degree in Thermal Energy Systems | 51650002 | Combustion in Thermal Engines | Semester 2 | Part 1 Basic considerations of combustion Part 2 Fundamentals of combustion Part 3 Combustion in MCIA Part 4 Combustion in TG Part 5 Combustion in TV Part 6 Emissions Part 7 Numerical methods in combustion |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040004 | Design of Electronic Systems for Communications | Semester 2 | 1. Electronic simulation with CADENCE. 2. Hardware description languages for analog circuits. 3. Basic block design. 4. Electronic system design for communications and signal conditioning. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280023 | Thermal Engineering | Semester 1 | - Principles of thermodynamics and equations of state. - Heat transfer mechanisms. - Thermal generation. - Cold production. - Power plant cycles. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040029 | Cyberphysical Systems and Hardware Security | Semester 1 | Block 1: Introduction and practical cases of cyber-physical systems Block 2: Real-time operating systems Block 3: Sensors and actuators Block 4: Communications, data collection and processing |
| M181 | Master's Degree in Chemical Engineering | 51810030 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| 208 | Degree in Chemical Engineering | 2080062 | Computational Mathematics | Semester 2 | Advanced concepts in the use of numerical software packages. Applications to engineering. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280039 | Robot Control and Programming | Semester 1 | CONTENTS: Robot control architecture. Robot control methods. Advanced robot programming. THEMATIC BLOCKS: Block 1: Introduction Block 2: Manipulator arms Block 3: Mobile robotics |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560023 | Business Organization and Management | Semester 1 | 1. Business Economic Analysis. 2. Investment Analysis. 3. Economic Control System. 4. Business Financial Analysis. |
| 199 | Degree in Telecommunications Technology Engineering | 1990020 | Communication Theory | Semester 2 | Mathematical, physical, and statistical foundations of communication systems. Information theory. Analog and digital modulations. Noise and noise figure. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940040 | Perception in Automatics and Robotics | Semester 2 | 1 Inspection: texture analysis 2 Detection and monitoring: motion, Kalman filter 3 Quality control: K-means, k-distance classifier, RN 4 Localization, mapping: position estimation, environment representation, map creation. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210029 | Savings and Energy Efficiency | Semester 2 | 1. Introduction 2. Energy Savings and Efficiency in Buildings: Demand. 3. Energy Savings and Efficiency in Buildings: Facilities. 4. Energy Savings and Efficiency in Industrial Thermal Facilities. 5. Energy Audits and Management Systems. |
| M143 | Master's Degree in Aeronautical Engineering | 51430016 | Composite material mechanics | Semester 2 | Thematic blocks: Morphology and manufacturing. Behavior of a sheet. General theory of laminates. Beams and plates. Joints. Acceptance and requalification tests. Covered topics: 1. Introduction to composite materials. 2. Law of behavior of a sheet. 3. Mechanical behavior of a sheet. 4. Mechanical behavior of a laminate. 5. Analysis of structural elements of composite material. 6. Joints in composite materials. 7. Acceptance and requalification tests. Practical sessions: 1. Manufacturing of a laminate. 2. Preparation of test specimens. 3. Characterization tests. 4. Acceptance and requalification tests. 5. Determination of the strength of a laminate. 6. Finite element modeling. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630006 | Integrated Operations Management in Production and Service Systems | Semester 1 | I) Advanced production design and planning techniques. II) Advanced production scheduling and control techniques. |
| 208 | Degree in Chemical Engineering | 2080024 | General Electronics | Semester 1 | Devices. Polarization. Amplifiers. The Operational Amplifier and its Applications. Logic Families. Introduction to Digital Electronics. Introduction to Communications. |
| M143 | Master's Degree in Aeronautical Engineering | 51430048 | Electrotechnical Accessories | Semester 2 | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210004 | Mathematics II | Semester 1 | Functions and derivatives. Integration. Taylor polynomials and series. Ordinary differential equations. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040017 | Biosensors and Bioelectronics | Semester 1 | Theoretical part: 1st - Introduction. - Presentation of the subject. Biology, medicine and electronics. Example of devices. 2nd - Biosensors. - Typology, interfaces, integration and applications. 3rd - Bioelectronics. - Biomedical/bioelectronic devices, quality management and certification, battery-less devices, and energy harvesting. Practical part: 1st - Functional and safety requirements. 2nd - Development of a real bioelectronic system. |
| 225 | Degree in Civil Engineering | 2250042 | Metal Structures II | Semester 2 | I. Plate buckling. II. Supports and anchorages of steel structures. III. Technology of composite structures. IV. Regulations and calculation bases for composite structures. V. Limit states of strength and instability of composite beams and supports. VI. Connectors. VII. Fitness for service. VIII. Composite floors. IX. Tanks and silos. X. Control, protection and maintenance of steel and composite structures. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210043 | Substations and High Voltage Lines (EL) | Semester 1 | Power line calculations, electrical model of power lines , power line capacity limits, HV switchgear and installations, substations , grounding , insulation coordination |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280032 | Integrated Projects | Semester 2 | CONTENTS: Project methodology, organization, and management. THEMATIC BLOCKS: Block I. INTRODUCTION TO INTEGRATED PROJECTS. Block II. PROJECT ORGANIZATION. Block III. PROJECT MANAGEMENT AND IMPLEMENTATION. |
| M164 | Master's Degree in Electrical Energy Systems | 51640010 | Metaheuristic Optimization and Prediction in Electrical Systems | Semester 1 | 1. Classification Techniques ¿ Kohonen Networks ¿ Competitive Networks ¿ C-clustering ¿ 2. Prediction Methods. ¿ Ar and Arx Models ¿ Ma, Arma and Armax Models ¿ ARIMA Models ¿ Neural Networks. ¿ Neighbors Technique. 3. Optimization Techniques. ¿ Genetic Algorithms. ¿ Particle Swarm Optimization Algorithms ¿ Tabu Search ¿ Simulated Annealing 4. Introduction to Stochastic Programming |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830016 | Environmental Systems | Semester 2 | Descriptors: Ecosystems and natural resources. Ecological systems: disturbances and pollution. Alteration of ecological factors. Block I. Ecosystems and natural resources. Block II. Ecological systems: disturbances and pollution. Block III. Alteration of ecological factors. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930027 | Energy Technology (MIAM) | Semester 1 | BLOCK 1 - REFRIGERATION TECHNOLOGY 1.01 Introduction 1.02 Physical and Thermodynamic Bases 1.03 Simple mechanical compression cycle 1.04 Multiple compression 1.05 Compressor technology 1.06 Evaporator and condenser technology 1.07 Accessories and refrigerants BLOCK 2 - INDUSTRIAL THERMAL INSTALLATIONS 2.01 Heat transfer fluids 2.02 Water vapor 2.03 Steam traps 2.04 Flash evaporation recovery 2.05 Distribution networks 2.06 Auxiliary equipment |
| 208 | Degree in Chemical Engineering | 2080056 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930038 | Environmental Quality Assessment | Semester 1 | - Sampling and analysis of environmental pollutants. - Automated methods for analyzing environmental pollutants. - Characterization and analysis of solid waste. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210012 | Circular Economy and Sustainability (DIS) | Semester 1 | Sustainability and environmental management. Circular economy and waste. Economy and the environment. Quantifying sustainability. Recycling. Ecodesign. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920032 | Application of Computational Methods to Mechanical Design | Semester 2 | The contents of the subject are structured in four blocks: A. DYNAMICS: which covers objectives 5) and 6). B. PLASTICITY: which includes objective 3). C. FRACTURE AND FATIGUE MECHANICS: which includes objectives 1), 2) and 4). D. CONTACT: which considers objective 7). |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210060 | Control in Energy Systems | Semester 2 | Introduction to automation. Design and implementation of logic controllers. Programmable logic controllers. Control of power generation systems. |
| M181 | Master's Degree in Chemical Engineering | 51810018 | Refining and Petrochemicals | Semester 1 | Block I: Oil Industry Crude Oil Extraction (conventional and non-conventional processes) Desalination and Pretreatments Evaluation of Crude Oil Distillation (topping), obtaining LPG and Vacuum Distillation Hydrotreatments (HDS, Hydrocracking) Catalytic Reforming and FCC Alkylation and Isomerization Other treatments Hydrogen in refinery Block II: Petrochemicals Production of Benzene and its derivatives Production of Olefins and its derivatives Production of Methanol and its derivatives Block III: Expert seminars |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950015 | Operation and Control of Chemical Plants | Semester 2 | Chemical Plant Operations Plant-wide Control |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210053 | Thermal turbomachines (EN) | Semester 2 | I FUNDAMENTALS OF THERMAL TURBOMACHINES II BLADE CASCADES III AXIAL TURBOMACHINES IV RADIAL TURBOMACHINES V SIMILARITY ANALYSIS VI OFF-DESIGN OPERATION OF TURBOMACHINES VII INSTALLATIONS |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940036 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280009 | Physics II | Semester 2 | Electromagnetism, Fundamentals of Thermodynamics |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210010 | Mathematics III | Semester 2 | 1. Functions of several variables. Differentiability. 2. Optimization of scalar fields. 3. Differential geometry. 4. Multiple integrals. 5. Line integrals. 6. Surface integrals. |
| 208 | Degree in Chemical Engineering | 2080008 | Physics II | Semester 2 | Electromagnetism, Structure of Matter and Thermodynamics. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210054 | Electrical Systems in Power Plants | Semester 1 | Electric power generation systems, alternators, specific protections for power plants. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040019 | Cloud application deployment | Semester 1 | Introduction to Cloud Computing, Data Centers , Distributed Systems Paradigms, Cloud Data Storage, Container and Infrastructure Virtualization and Orchestration, Vendor Overview |
| 225 | Degree in Civil Engineering | 2250046 | Transportation Engineering | Semester 1 | The transportation system. Mobility and flows. Demand analysis. Modality and modal split. Networks and allocation. Modeling and simulation. Demand and flow estimation and forecasting. |
| 225 | Degree in Civil Engineering | 2250045 | Railway infrastructure | Semester 2 | Block 1: AUSCULTATION, MONITORING AND MAINTENANCE Topic 1. Generalities Topic 2. Geometric auscultation of the track Topic 3. Project parameters of the track layout Topic 4. Machinery and track construction Topic 5. Characterization of the track geometry Topic 6. Monitoring vehicles Topic 7. Measurement systems Topic 8. Geometric quality levels Topic 9. Track renewal operations Topic 10. Railway maintenance Topic 11. Rail defects Block 2: INFRASTRUCTURE ELEMENTS Topic 12. Platform: design and construction Topic 13. Railway bridges Topic 14. Railway tunnels Topic 15. Drainage Topic 16. Factory works Topic 17. Line systems and equipment Topic 18. Railway electrification Topic 19. Vibrations and induced noise Block 3: OPERATIONS Topic 20. Signaling Topic 21. Interlockings Topic 22. Line capacity Topic 23. Operations scheduling Topic 24. Right of way Topic 25. Safety BASIC BIBLIOGRAPHY Alias, J. Le Rail. Eyrolles, 1987. Arqués, JL Engineering and Management of Maintenance in the Railway Sector. Diaz de Santos, 2009 Esveld, C. Modern Railway Track. MRT Productions, 1989. Hay, WW Railroad Engineering. John Wiley & Sons,1982. Oliveros, F.; Rodriguez, M.; Megia, M. Treaty of Railways II. Civil Engineering and Installations. Ed. Rueda, 1980. Pachl, J. Railway Operation and Control. VTD Rail Publishing, 2009. Profillidis, VA Railway Management and Engineering. 3rd Ed. Ashgate 2006. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210022 | Control Engineering (AR, EIDTE) | Semester 1 | Analysis and synthesis of discrete-time feedback systems. State-variable-based control. Computer control. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280024 | Electrical Installations and Machines | Semester 1 | Medium and low voltage electrical installations, transformers, electric motors. |
| M164 | Master's Degree in Electrical Energy Systems | 51640004 | Ac/dc Devices and Systems | Semester 1 | Topic 1. Problem-solving techniques for transmission networks and conventional solutions. Topic 2. FACTS for transmission I: parallel connection. Topic 3. FACTS for transmission II: series and hybrid connection. Topic 4. Problem-solving techniques for distribution networks and conventional solutions. Topic 5. FACTS for distribution I: Voltage source converter. Topic 6. FACTS for distribution II: Applications. Topic 7. Other FACTS devices used in distribution. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630015 | Advanced Production Systems | Semester 1 | Cellular manufacturing and sustainable manufacturing. Intelligent production planning, scheduling, and control systems. |
| M181 | Master's Degree in Chemical Engineering | 51810021 | Management Control and Logistics Techniques | Semester 1 | Dashboards. Strategic and Functional Indicators. Strategic, Tactical, and Operational Analysis Techniques for Business Management. Logistics |
| M190 | Master's Degree in Civil Engineering (2019) | 51900022 | Project and construction management | Semester 2 | Methodology, organization, and management of civil construction projects; regulations. Construction projects for land, water, and maritime transport infrastructure. Civil construction project management. |
| 199 | Degree in Telecommunications Technology Engineering | 1990033 | Audio, Video and Television Equipment and Systems | Semester 1 | Systems, equipment, headends, and installations for television, audio, and video, both fixed and mobile. Receivers and translators. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980038 | High Energy Efficiency Buildings | Semester 1 | Reduction of energy demand for heating and cooling. Increased energy efficiency in facilities. Theoretical bases for the development of high energy efficiency building projects (Energy rating. Regulations). Natural cooling techniques. Demand-side management (DSM). |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210063 | Advanced design in PLM (Product Lifecycle Management) environments | Semester 2 | Module 1: Introduction to the PLM methodology Module 2: Product lifecycle engineering Module 3: PLM technological tools Module 4: Product design and engineering in PLM Module 5: Innovation and sustainability Module 6: Applied project The previous blocks materialize the contents of the subject that contribute to the development of the HD-CCTT-5 result of the title and that correspond to: "Being able to apply advanced techniques and tools for design, modeling, simulation and management of the life cycle of complex industrial products in collaborative digital environments." |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960049 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950009 | Reactor Engineering | Semester 2 | Multiphase reactors. Fixed-bed catalytic reactors. Fluidized-bed reactors. Three-phase reactors |
| M165 | Master's Degree in Thermal Energy Systems | 51650006 | Design, Operation and Maintenance of Steam Power Plants | Semester 1 | I. INTRODUCTION. II. COMBUSTION PRINCIPLES. III. STEAM GENERATORS. IV. STEAM TURBINES. V. STEAM TURBINE LOSSES. VI. MONITORING AND TESTING. VII. STEAM TURBINE REGULATION. VIII. STEAM TURBINE DAMAGE IX. EMISSIONS FROM STEAM TURBINE PLANTS. X. OPERATION AND MAINTENANCE. |
| M143 | Master's Degree in Aeronautical Engineering | 51430017 | Aeronautical manufacturing processes | Semester 1 | BLOCK I: Basis for the Analysis of Forming Processes . Plastic Forming. Machining. BLOCK II: Design for Manufacturing and Assembly (DFMA). DFM for Consolidation, Plastic Deformation, and Machining Processes. Design for Assembly (DFA). BLOCK III: Non-Conventional Forming Processes . Advanced Machining Processes. Additive Manufacturing. Processes and Applications. |
| 208 | Degree in Chemical Engineering | 2080009 | Mathematics III | Semester 2 | Knowledge of advanced aspects of Mathematical Analysis and its applications: Differential and integral calculus in several variables. |
| 208 | Degree in Chemical Engineering | 2080048 | Projects | Semester 1 | Methodology, organization and project management. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980044 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 197 | Degree in Aerospace Engineering | 1970068 | Consumer electronics | Semester 2 | Laptops, audio and video playback, digital cameras, video game consoles, television and digital audio, mobile phones, PDAs. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270018 | Electronic Technology | Semester 2 | Electronic devices and circuits. Microprocessors. Applications. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210007 | Statistics and Operations Research | Semester 2 | Statistics and optimization. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630018 | Data Analysis and Processing | Semester 1 | I) Description of Univariate and Multivariate Data II) Analysis of Multivariate Data III) Experimental Design Models IV) General Linear Model V) Time Series Analysis VI) Diagnosis and criticism of the model |
| 208 | Degree in Chemical Engineering | 2080057 | Bioengineering | Semester 2 | - Basic concepts and applications in bioengineering. - Future development prospects. - Knowledge of the technological areas involved. - Medical applications. |
| 203 | Degree in Industrial Technology Engineering | 2030109 | Chemical technology | Semester 1 | Raw materials for chemical processes. Energy sources. Organic and inorganic chemical technology. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270002 | Computing | Semester 1 | Computer Fundamentals. Algorithms. Programming. Introduction to operating systems, databases, and software with applications in engineering. |
| 225 | Degree in Civil Engineering | 2250041 | Concrete Structures II | Semester 2 | Prestressing idea Technique and materials Evolution and deferred deformations Study of losses Axial behavior Bending Shear Layout Composite sections Evolutionary construction |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270023 | Quantitative Management Methods | Semester 1 | Integer and mixed linear programming. Application to modeling using continuous, integer, and mixed linear programming and problem solving in organizational engineering. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280022 | Hydraulic engineer | Semester 1 | Principles of Fluid Mechanics. Hydraulic Installations. Part I. Introduction . Part II. Statics and Dynamics of Fluids. Part III. General Equations and Dimensional Analysis. Part IV. Turbulent Incompressible Flow through Conduits. Part V. Turbomachinery and Hydraulic Installations. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280025 | Digital Signal Processing | Semester 1 | Linear digital systems and related functions and transforms, and their application to engineering problems. Information processing using digital signal processing techniques. |
| 197 | Degree in Aerospace Engineering | 1970071 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| 197 | Degree in Aerospace Engineering | 1970052 | Quality Management | Semester 2 | BLOCK I. INTRODUCTION TOPIC I. QUALITY: FUNDAMENTALS AND VOCABULARY - Terms and definitions according to UNE EN ISO 9000 - Costs of conformity and non-conformity. Total cost optimum environment. - Guidelines for obtaining financial and economic benefits UNE ISO 10014. - Introduction to quality infrastructure - Quality management principles according to UNE EN ISO 9000 - Quality management systems approach, process-based quality management system model, continuous improvement objective and relationship with excellence models. BLOCK II. AEROSPACE 9100 QUALITY MANAGEMENT SYSTEM TOPIC II. QUALITY MANAGEMENT SYSTEM 9100 - Quality management system requirements according to UNE EN ISO 9100, UNE EN ISO 9120 Aerospace material - Distributors and warehouses, and UNE EN ISO 9110 Aerospace material - Maintenance organizations. - Guidelines for the documentation of quality management systems UNE 66925. - Guidelines for quality plans UNE ISO 10005. TOPIC III. GUIDES AND DIRECTIVES FOR DEVELOPING THE QUALITY MANAGEMENT SYSTEM. - Guide for the implementation of indicator systems UNE 66175. - Guidelines for the audit of management systems UNE EN ISO 19011. - Guidelines for the measurement, monitoring and analysis of customer satisfaction UNE 66176. - Guidelines for the treatment of complaints in organizations UNE ISO 10002. - Guidance on the use of statistical techniques in the quality management system 9001- UNE ISO 10017. BLOCK III. ENVIRONMENT AND INTEGRATION OF MANAGEMENT SYSTEMS TOPIC IV. ENVIRONMENTAL MANAGEMENT SYSTEM. - Environmental management system UNE EN ISO 14001. Morphology of the environmental management system. Identification and evaluation of environmental aspects. TOPIC V. INTRODUCTION TO SYSTEMS INTEGRATION - Management for the sustained success of an organization according to UNE EN ISO 9004. - Introduction to business excellence models: Japanese model (Deming), American model (Malcom Baldrige) and European model (European Foundation for Quality Management). |
| 197 | Degree in Aerospace Engineering | 1970017 | Electrical engineering | Semester 2 | Circuit components, DC circuits, AC circuits, three-phase circuits, fundamentals of electrical machines. |
| M181 | Master's Degree in Chemical Engineering | 51810004 | Advanced Control of Chemical Processes | Semester 1 | Thematic Block 1. Classical methods of advanced chemical process control: feedforward control, cascade control, control of systems with dead times, and other structures such as split-range control and maximum control. Thematic Block 2: Introduction to computer control. Analysis and synthesis methods for computer control systems for chemical processes. Thematic Block 3: Introduction to model-based predictive control. |
| 199 | Degree in Telecommunications Technology Engineering | 1990039 | Software Engineering | Semester 2 | Object-Oriented. UML. Java |
| 203 | Degree in Industrial Technology Engineering | 2030154 | Integrated Production Systems | Semester 2 | BLOCK I: INTRODUCTION TO INTEGRATED PRODUCTION SYSTEMS BLOCK II: ANALYSIS OF THE CURRENT SITUATION BLOCK III: IMPROVEMENTS FOCUSED ON PROCESS SYNCHRONIZATION BLOCK IV: IMPROVEMENTS FOCUSED ON PROCESS PERFORMANCE BLOCK V: NEW TECHNOLOGIES APPLIED TO INTEGRATED PRODUCTION SYSTEMS. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940047 | Electronic Systems for Smart Grids | Semester 1 | Chapter I: Topologies of advanced power converters (smart Inverter) Chapter II: Modulation techniques for smat inverters Chapter III: Control strategies for smart converters Chapter IV: Technologies associated with the development of smart grids |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960032 | Data Analysis and Processing | Semester 1 | I) Description of Univariate and Multivariate Data II) Analysis of Multivariate Data III) Experimental Design Models IV) General Linear Model V) Time Series Analysis VI) Diagnosis and criticism of the model |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270065 | Industrial Computing | Semester 1 | CONTENT: Real-Time Computer Systems. Industrial communications systems. THEMATIC BLOCKS: THEORY: Topic 1. Introduction to real-time systems Topic 2. Complements on computers, operating systems and languages Topic 3. Concurrency and timing services Topic 4: Synchronization services and communication through shared memory Topic 6: Communication through message passing and communications networks PRACTICES: 1) Class exercises 2) Laboratory practices on the content of the subject |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210046 | Wind Energy | Semester 1 | General characteristics of various wind turbines. Selection of wind farm sites: onshore and offshore wind farms; stand-alone systems. Main components: rotors, structures, regulation and control systems, generators. Economic and environmental considerations. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270025 | Information systems | Semester 1 | Study of Business Information Systems. Types of information systems. Information integration. Information system design: methodologies and tools. Usability and quality of information systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560020 | Industrial automation | Semester 2 | Know and master sequential logic control system modeling techniques. PLC architecture, industrial controller programming, and real-life case studies of production plants. Automation project development and documentation. |
| 208 | Degree in Chemical Engineering | 2080032 | Process engineering | Semester 2 | Topic 1. The Chemical Industry. Topic 2. Process Engineering. Topic 3. Equipment and Processes. Topic 4. Process Diagrams. Topic 5. Process Analysis. Topic 6. Material and Energy Balances in Complex Processes. Topic 7. Preliminary Design of Process Equipment. Specification Sheets. Topic 8. Economic Analysis in Process Engineering. Topic 9. Technical Documents in Process Engineering. Topic 10. Auxiliaries in Chemical Processes. Topic 11. Fuels, Furnaces, and Boilers. Topic 12. Steam Installations Topic 13. Compressed Air Installations. Topic 14. Regulations. Industrial Regulations. Practices: Analysis of an Inorganic or Organic Chemical Technology Process |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630008 | Management Information Systems | Semester 1 | The course content will be tailored to the following descriptors: - Search, manage, and analyze relevant information for decision-making, as well as understand and use business information systems to support decision-making in the field of Industrial Organization. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280017 | Digital electronic | Semester 2 | Digital electronics, including small-, medium-, high-, and very-high-scale integration blocks. Mixed-signal electronics, including the principles of matching, analog-to-digital, and digital-to-analog conversion. Programmable devices, including FPGAs. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900015 | Mechanics of Continuous Media | Semester 2 | Part 1. EXTENSION OF THE THEORY OF ELASTICITY. Thermoelasticity. Plastification criteria. Part 2. THEORY OF PLASTICITY. The Perfect Elastoplastic Model (The 1D case, Basic postulates, The 3D case, Equivalent plastic deformation, Plastic collapse, Limit analysis). ELASTOPLASTIC CALCULATION OF BAR STRUCTURES. Plastic behavior of a bar subjected to bending moment, shear and axial force, Elastoplastic equations of a bar and a structure, Collapse of a bar structure, Limit analysis, Calculation of the collapse load and of the maximum displacements and strains at collapse. Application of a FEM code to an elastoplastic problem. Part 3. FRACTURE MECHANICS. Introduction and historical fractures. Approach to Linear Elastic Fracture Mechanics (LEFM) through the Theory of Elasticity. Plasticity at the crack edge. Approach to LEFM through energy balance. Calculation of the Stress Intensification Factor. Determination of material properties (Fracture toughness, R curve). Part 4. VISCOSITY THEORY. The Linear Viscoelastic Model (Creep and relaxation tests, Basic models, Integral formulation, The 3D case). The Nonlinear Viscoelastic Model, Creep (Creep under constant and variable stress, The 3D case, Estimation of rupture time). The Viscoplastic Model. Application of a FEM code to a viscoelastic problem. Seminars/lectures that will be part of the student's evaluation. Basic Bibliography Theory of Elasticity Authors: Federico París Edition: Edition 3, 2000 Publication: Elasticity and Strength of Materials Group, ETSI, University of Seville ISBN: 84-88783-32-9 SOLID MECHANICS. Theory of Plasticity. 3rd Year. Aeronautical Engineering. Authors: Rafael Picón Edition: 2012 Publication: Elasticity and Strength of Materials Group ETSI, University of Seville ISBN: 978-84-88783-92-9 Fracture Mechanics Authors: Federico París, Vladislav Mantic Edition: 2017 Publication: Elasticity and Strength of Materials Group ETSI, University of Seville ISBN: 978-84-88783-92-9 Engineering plasticity Authors: Calladine, C.R. Edition: 1969 Publication: Pergamon ISBN: 978-84-88783-92-9 Theory of plasticity Authors: Chakrabarty, J. Edition: 1987 Publication: McGraw Hill ISBN: 978-84-88783-92-9 Fracture Mechanics Authors: Janssen, M., Zuidema, J. Wanhill, R.J.H. Edition: 2002 Publication: Delft University Press ISBN: 978-84-88783-92-9 Fracture Mechanics An Introduction Authors: Gdoutos, EE Edition: 2nd Edition, 2005 Publication: Springer ISBN: 978-84-88783-92-9 Fracture Mechanics, Fundamentals and Applications Authors: Anderson, TL Edition: Fourth Edition, 2017 Publication: Taylor & Francis ISBN: 978-84-88783-92-9 BIBLIOGRAPHY Complementary: Questions of Elasticity Authors: Federico París, José Cañas Edition: 2012 Publication: Elasticity and Strength of Materials Group ETSI, University of Seville ISBN: 978-84-88783-92-9 Elasticity Exam Problems Authors: Antonio M. Blázquez, José Cañas, Federico Paris Edition: Edition Solid mechanics Solved exam problems (Plasticity) Authors: Rafael Picón Edition: 2012 Publication: Elasticity and Strength of Materials Group, ETSI, University of Seville ISBN: 978-84-88783-92-9 Exam problems in Fracture Mechanics Authors: Vladislav Mantic, Federico París Edition: 2014 Publication: Elasticity and Strength of Materials Group, ETSI, University of Seville ISBN: 978-84-88783-92-9 |
| M143 | Master's Degree in Aeronautical Engineering | 51430052 | Rational Mechanics Complements | Semester 1 | Extension to Kinematics and Vectorial Dynamics of Rigid Bodies. Analytical Formulation of Mechanics. Extension to Impulsive Dynamics. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210005 | Chemistry | Semester 1 | Topic 1. Stoichiometry. Topic 2. Thermochemistry. Topic 3. States of matter. Topic 4. Gases. Topic 5. Liquid-vapor equilibrium. Topic 6. Chemical kinetics. Topic 7. Free energy, spontaneity, and entropy. Topic 8. Chemical equilibrium. Topic 9. REDOX equilibrium. Electrochemistry. |
| 208 | Degree in Chemical Engineering | 2080033 | Electrical Installations and Machines | TO | I. DESCRIPTION OF ELECTRICAL SYSTEMS. II. THE TRANSFORMER. III. THE INDUCTION MOTOR. IV. SHORT-CIRCUIT CALCULATION V. LOW-VOLTAGE ELECTRICAL INSTALLATIONS. VI. MEDIUM-VOLTAGE DISTRIBUTION VII. HIGH-VOLTAGE TRANSPORTATION VIII. ELECTRICAL POWER GENERATION |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210022 | Electrical Installations and Machines | Semester 1 | Medium and low voltage electrical installations, transformers, electric motors. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270028 | Product Design and Innovation | Semester 2 | Product lifecycle analysis. Product design. Concurrent engineering. Design-based manufacturing. Innovation management. |
| 225 | Degree in Civil Engineering | 2250007 | Mathematics I | Semester 1 | Conics and quadrics. Reduced equations. Complex numbers. Rigid motion. Matrices, determinants, and systems of linear equations. Vector spaces. Orthogonality and best approximation. Eigenvalues and eigenvectors. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920049 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960046 | Intelligent Maintenance Systems | Semester 2 | Advanced systems and techniques to support (and optimize) maintenance management and the management of the resources required for its execution |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830017 | Energy Technology | Semester 1 | BLOCK 1 - REFRIGERATION TECHNOLOGY 1.01 Introduction 1.02 Physical and Thermodynamic Bases 1.03 Simple mechanical compression cycle 1.04 Multiple compression 1.05 Compressor technology 1.06 Evaporator and condenser technology 1.07 Accessories and refrigerants BLOCK 2 - INDUSTRIAL THERMAL INSTALLATIONS 2.01 Heat transfer fluids 2.02 Water vapor 2.03 Steam traps 2.04 Flash evaporation recovery 2.05 Distribution networks 2.06 Auxiliary equipment |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280018 | General Electronics | Semester 2 | 1. Electronic and photonic devices and components 2. Analysis and synthesis of electronic circuits 3. Analog electronics, including amplifiers, operational amplifiers, feedback, oscillators, and filters 4. Mixed-signal electronics, including the principles of matching, analog-to-digital and digital-to-analog conversion |
| 203 | Degree in Industrial Technology Engineering | 2030171 | Industrial electronics | Semester 1 | Programmable logic systems. Microprocessors and peripherals, microcontrollers. Digital signal processors. Embedded systems. Hardware/software co-design. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210127 | Advanced Fracture Mechanics and Fatigue | Semester 2 | BLOCK 1: Advanced Fracture Mechanics . Elasto-Plastic Fracture. Fracture in Quasi-Brittle Materials. BLOCK 2: Fatigue I. Fatigue behavior and growth modeling of small cracks. Fatigue under stress gradients in the small-crack regime. BLOCK 3: Fatigue II . Multiaxial Fatigue. Fretting Fatigue. Fatigue under Random Loading. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900034 | Territorial and Civil Infrastructure Planning | Semester 1 | BLOCK 1. TERRITORIAL PLANNING. 1. The territorial planning heritage: Relevant examples of regional and subregional planning. 2. The Regulatory Framework: Planning laws at the territorial scale and the specificity of Andalusian legislation as an integration of the urban and territorial scales. 3. Territorial planning and its areas of action (City Systems, Protection Zones and Structural Systems of the Territory); its implementation at the regional and subregional-county scales and its determinations on lower-level planning. 4. Urban planning of strategic areas: detailed planning within the framework of the territorial scale. BLOCK 2. THE SPATIAL DATA INFRASTRUCTURE FOR PLANNING. 1. Fundamentals of Geographic Information Systems (GIS). 2. Spatial data. Infrastructure and Organization. 3. Applications in the field of territorial planning. Analysis Tools and Results. 4 GIS and Building Information Model (BIM) Integration. BLOCK 3: TRANSPORTATION INFRASTRUCTURE PLANNING. 1. Fundamentals of Infrastructure Planning. 2. Analysis and Selection of Investments in Civil Infrastructure Planning. Public and Private Financing of Civil Infrastructure. 3. Urban Traffic. Accessibility in Transport Infrastructure Networks. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270068 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| 203 | Degree in Industrial Technology Engineering | 2030060 | Separation Operations | TO | Operations controlled by mass transfer, momentum transfer, and heat transfer |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270052 | Process Reengineering | Semester 1 | Process modeling. Process redesign. Process mapping. Performance indicators. Continuous improvement systems. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270001 | Physics I | Semester 1 | Mechanics, oscillations and waves. |
| 203 | Degree in Industrial Technology Engineering | 2030152 | Advanced Electronic Systems | Semester 2 | Architecture of microprocessor-based systems. Design and programming tools. Building block design. Hardware and software debugging and optimization. Embedded systems for industrial control. Signal and systems analysis techniques. Digital filter design. Electronic systems for digital signal processing. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560022 | Thermal Engineering | TO | * Block 1. Heat Transmission (41 hours type B + 2 hours type E + 2 hours type G): General concepts on heat transmission. Fundamentals and characterization of heat transmission by conduction: modeling, steady state and extended surfaces. Fundamentals and characterization of heat transmission by radiation: laws, modeling, form factors, and radiant exchange in enclosures in non-participating medium. Fundamentals and characterization of heat transmission by convection: modeling and quantification. Study of applications through a combination of mechanisms and problem solving. * Block 2. Energy Technology (20.5 hours type B + 1 hour type E + 1 hour type G). Fundamentals, design and evaluation of heat exchangers. Fundamentals, design and evaluation of heat generation systems. Block 3. Fundamentals of Thermal Machines and Engines (20.5 hours type B + 1 hour type E + 1 hour type G) Thermal machines and engines and their applications Fundamentals of systems based on Steam Turbine Fundamentals of systems based on Gas Turbine Fundamentals of Alternative Internal Combustion Engines : |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940045 | Electronic Systems for Aerospace Applications | Semester 2 | It has four thematic blocks: Block I. Testing and qualification of electronic components Block II. Testing and qualification of complex electronic systems Block III. Design for qualification of programmable electronic devices for aeronautics and space Block IV. Design of aerospace systems |
| M143 | Master's Degree in Aeronautical Engineering | 51430051 | Orbital Mechanics Complements | Semester 1 | Orbital Mechanics. Space Vehicle Dynamics. Space Vehicle Systems. |
| 208 | Degree in Chemical Engineering | 2080023 | Chemical analysis | Semester 1 | - Unit operations in chemical analysis. - Chemometrics. - Classical analysis methods. - Spectroscopic methods. - Electrochemical methods. - Separation methods. - Mass spectrometry. - Thermogravimetric methods. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550004 | Solid Dynamics | Semester 1 | BLOCK 1. VIBRATIONS OF LINEAR SYSTEMS WITH N DOF. RANDOM VIBRATIONS OF LINEAR VIBRATORY SYSTEMS. BLOCK 2. EXPERIMENTAL MODAL ANALYSIS. VIBRATIONS IN ROTORS. BLOCK 3. DAMAGE DETECTION IN MACHINERY. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210048 | Electronic Technology | Semester 1 | Synchronous and asynchronous digital circuits. Digital subsystems. High-level programming languages. Introduction to microprocessors. Electronic design of digital systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210113 | Application of Computational Methods to Mechanical Design | Semester 2 | The contents of the subject are structured in four blocks: A. DYNAMICS: which covers objectives 5) and 6). B. PLASTICITY: which includes objective 3). C. FRACTURE AND FATIGUE MECHANICS: which includes objectives 1), 2) and 4). D. CONTACT: which considers objective 7). |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210117 | Dynamics of Multibody Systems | Semester 2 | The course consists of two thematic blocks: - Computational Kinematics - Computational Dynamics The first block, Computational Kinematics, shows the machine modeling techniques for simulation, including the selection of coordinates and reference systems and the kinematic restrictions to which they are subject. Based on the model, the computational techniques for analyzing position, velocity and acceleration that allow kinematic simulation are shown. The second block, Computational Dynamics, shows the automatic formulation and calculation of the equations of motion of multibody systems in their ODE and DAE forms. The block continues by showing the numerical methods for solving these equations in the time domain that allow the dynamic simulation of machines. |
| M165 | Master's Degree in Thermal Energy Systems | 51650007 | High Energy Efficiency Buildings | Semester 1 | Reduction of energy demand for heating and cooling. Increased energy efficiency in facilities. Theoretical bases for the development of high energy efficiency building projects (Energy rating. Regulations). Natural cooling techniques. Demand-side management (DSM). |
| 225 | Degree in Civil Engineering | 2250039 | Prefabricated constructions | Semester 1 | THE SUBJECT IS STRUCTURED IN 3 THEMATIC BLOCKS: The subject consists of 3 THEMATIC BLOCKS: Thematic Block I.- INTRODUCTION AND GENERAL CONCEPTS (2 WEEKS): TOPIC 01.- Introduction to the subject. Teaching organization. General concepts TOPIC 02.- Dimensional and modular coordination. Thematic Block II.- STRUCTURAL SYSTEMS (5 weeks) TOPIC 03.- Structural systems with linear elements I. Foundations. TOPIC 04.- Structural systems with linear elements II. TOPIC 05.- Systems of large panels and three-dimensional modules TOPIC 06.- Manufacturing process. Group visit to the PRECON Prefabricated Factory, in Dos Hermanas, in one morning at a time to be defined, with which the established credits are completed. TOPIC 07.- Horizontal plane structural elements. Forgings. TOPIC 08.- Prefabricated elements for Civil Engineering projects I. TOPIC 09.- Prefabricated elements for Civil Engineering projects II. Thematic Block III.- NON-STRUCTURAL SYSTEMS (8 weeks) TOPIC 10.- Lightweight facades. TOPIC 11.- Lightweight prefabricated roofs. TOPIC 12.- Cementitious matrix facade panels. GRC. TOPIC 13.- Reinforced concrete facade panels. TOPIC 14.- Constructive configuration of prefabricated buildings. TOPIC 15.- Regulations, documentation and planimetry for the development of a project with prefabricated elements. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560014 | electronics | Semester 2 | Semiconductor devices. The operational amplifier. Analog circuits. Introduction to power electronics. Introduction to digital electronics. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900001 | Supply, Sanitation and Waste Management | Semester 2 | Water supply and distribution. Distribution networks. Water treatment for supply. Design of collectors and sanitation networks. Urban water treatment. Design of treatment plants (DWTP) and wastewater treatment plants (WWTP). Urban water cycle management. Design and management of urban waste collection systems. Calculation, design, and operation of urban waste management facilities. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600017 | Electronic Systems for Smart Grids | Semester 1 | Chapter I: Topologies of advanced power converters (smart Inverter) Chapter II: Modulation techniques for smat inverters Chapter III: Control strategies for smart converters Chapter IV: Technologies associated with the development of smart grids |
| 197 | Degree in Aerospace Engineering | 1970023 | Computer Aided Design and Manufacturing | Semester 1 | Design techniques and virtual generation of three-dimensional solids and their assembly for aerospace components. Automatic and standardized production of aeronautical project plans. Computer-aided manufacturing. |
| 197 | Degree in Aerospace Engineering | 1970029 | Airport Operations and Air Transport | Semester 1 | - International Standards and Organizations. - Civil Aviation Legislation and Administration. - Airport Operations. - Transport Aircraft Operations. |
| 199 | Degree in Telecommunications Technology Engineering | 1990065 | Emerging Communications Systems | Semester 1 | Elements, specifications, architecture, and organization of emerging communications systems. New technologies. |
| 199 | Degree in Telecommunications Technology Engineering | 1990030 | Advanced Digital Communications | Semester 2 | Channel coding. Block and convolutional codes. Digital transmission over band-limited channels. Multicarrier systems. Spread spectrum signals for digital communications. MIMO systems. Multiuser communications. Fading channels: characterization and signaling. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210005 | Kinematics and Machine Dynamics (IMF) | Semester 1 | Kinematic analysis of mechanisms. Dynamic analysis of mechanisms. Synthesis of mechanisms. Numerical methods applied to kinematic and dynamic analysis. |
| 225 | Degree in Civil Engineering | 2250020 | Construction Materials Technology | Semester 2 | - Mechanical and technological properties of construction materials. - Technology of materials used in construction and their basic products: stone, ceramic, hydraulic binders, concrete, wood, metal, polymer, bituminous, glass, and composites. - Characterization and quality control. - Life cycle of construction materials. - Construction materials laboratory. |
| 199 | Degree in Telecommunications Technology Engineering | 1990016 | Automatic control | Semester 1 | System modeling and identification. Time-response analysis. Stability analysis. Principles and techniques of system and process control. Control system design and implementation. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920039 | Fundamentals and Simulation of Manufacturing Processes | Semester 2 | - Fundamentals of Forming Process Analysis: Plastic Forming; Machining; Non-Conventional Processes. - Design for Manufacturing and Assembly (DFMA). - Manufacturing Process Simulation. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560035 | Home automation | Semester 2 | The course content will be divided into three main thematic blocks: - Block I: Introduction to the basic concept of home automation networks in buildings. The basic characteristics of home automation systems will be explained and detailed, including their fundamental elements and the relationships between them. The structure and organization of basic installations in smart homes and buildings in general will be detailed. - Block II: Description of the main home automation technologies available on the market, along with the protocols used. - Block III: Introduction to service robotics and the concept of smart cities. |
| 199 | Degree in Telecommunications Technology Engineering | 1990047 | Teletraffic | Semester 2 | Queuing Theory Basic concepts of teletraffic and quality of service Queuing models Dimensioning telecommunication networks |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600016 | Electronic Systems for Renewable Energy Management | Semester 2 | Chapter I. Introduction to electronic systems for renewable energy management Chapter II. Wind energy Chapter III. Photovoltaic energy Chapter IV. FACTS systems, energy storage and electric vehicles |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930045 | Industrial Security | Semester 1 | After a general introduction, the course will be divided into the following fundamental sections: 1. Overview of Industrial Safety. 2. The different stages in the implementation of an ES: Hazard Identification Techniques. 3. The different stages in the implementation of an ES: Consequence Analysis. 4. Quantitative Risk Analysis (RCA). 5. Risk Reduction Techniques applied to the design of chemical plants. 6. Emergency Plan. Inside and outside the factory. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920046 | Advanced Mathematical Methods in Engineering | Semester 1 | Numerical methods for solving problems involving ordinary differential equations. Stability theory of dynamical systems. Long-term and global behavior. Continuation methods for ordinary differential equations. |
| 208 | Degree in Chemical Engineering | 2080007 | Statistics and Operations Research | Semester 2 | Ability to apply knowledge of statistics and optimization. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830012 | Noise Pollution Engineering and Control | Semester 2 | Topic 1: Basic acoustic concepts: definitions, assessment quantities, the audition process, frequency analysis, etc. Topic 2: Acoustic indices: noise assessment units, acoustic assessment indices Topic 3: Limits and regulations for environmental noise management. International analysis and national analysis (national requirements, regional requirements and local requirements) Topic 4: Control by absorption. Acoustic absorption and reverberation time. Topic 5: Sound radiation through the air. Engineering method for predicting sound levels in open and closed spaces. Topic 6: Noise control through shielding. Design and calculations of acoustic screens Topic 7: Acoustic insulation against airborne noise and structure-borne noise: soundproofing and acoustic encapsulation. Topic 8: Noise control using silencers. Silencers for rooms, silencers for fans and other HVAC equipment, silencers for motors and compressors, silencers for valves and ejectors. Topic 9: Strategic Noise Maps and Action Plans. Road noise maps, railway line noise maps, airport noise footprints, port noise maps, and urban agglomeration noise maps. International standards for assessing the emissions of mobile noise sources (road traffic, rail traffic, and air traffic). European Union requirements and trends in other countries in the assessment of environmental noise pollution and action plans aimed at reducing it. Topic 10: Environmental noise measurement methods. Noise measurement instrumentation and equipment. International reference standards. Importance of the method for assessing compliance with limits. Topic 11: Acoustic study of noise sources and activities. Methodology for justifying compliance with regulatory limits using noise prediction methods. |
| 197 | Degree in Aerospace Engineering | 1970007 | Physics II | Semester 2 | Electromagnetism. Fundamentals of Thermodynamics. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600007 | Microsystems and Nanotechnologies | Semester 2 | THEMATIC BLOCKS 1. INTRODUCTION TO MICROSYSTEMS. 2. APPLICATIONS OF MICROSYSTEMS. 3. DESIGN AND MANUFACTURING A MICROSYSTEM. 4. INTRODUCTION TO NANOTECHNOLOGY. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040022 | Professional Practice of Engineering | Semester 2 | 1. INTRODUCTION TO ENGINEERING. APPLICATION TO THE CASE OF INDUSTRIAL ENGINEERING a. HISTORY b. PROFILE c. WORKS d. RECOGNITIONS 2. THE ENGINEERING MAP. APPLICATION TO INDUSTRIAL ENGINEERING a. SPANISH ENGINEERING FIRMS b. ENGINEERING FIRMS WORLDWIDE c. ENGINEERING ORGANIZATIONS d. PROFESSIONAL ASSOCIATIONS e. PROFESSIONAL ENGINEERING CERTIFICATIONS f. ENGINEERING DEGREES g. THE PRACTICE OF ENGINEERING AROUND THE WORLD h. INDUSTRIAL ENGINEERING STUDIES i. SOFT SKILLS FOR WORKING AS AN ENGINEER j. SUCCESS IN THE ENGINEERING PROFESSION 3. THE LEGISLATIVE FRAMEWORK OF THE ENGINEER a. COMPETENCES, ATTRIBUTIONS AND COMPETENT TECHNICIANS b. PROFESSIONAL ATTRIBUTIONS OF THE ENGINEER. ATTRIBUTIONS OF THE INDUSTRIAL ENGINEER c. PROJECT DRAFTING d. PROFESSIONAL FEES e. INDUSTRIAL LEGISLATION, RULES AND REGULATIONS f. SUBMISSION OF DOCUMENTS TO THE ADMINISTRATION g. REGULATION OF THE PROFESSION IN VARIOUS COUNTRIES h. THE CIVIL AND CRIMINAL LIABILITY OF THE ENGINEER i. JUDGMENTS FOR ATTRIBUTIONS j. JUDGMENTS FOR CIVIL LIABILITY k. PROFESSIONAL ETHICS l. COLLEGE VISA 4. FIELDS OF ACTIVITY OF THE ENGINEER. APPLICATION TO INDUSTRIAL ENGINEERING a. THE ENGINEER IN THE INDUSTRIAL COMPANY b. THE ENGINEER AS A BUSINESS DEVELOPER c. THE ENGINEER IN THE PUBLIC SERVICE d. THE ENGINEER IN THE ENGINEERING COMPANY e. THE ENGINEER IN THE SERVICE COMPANY f. THE ENGINEER IN THE MAINTENANCE COMPANY g. OCCUPATION BAROMETER FOR INDUSTRIAL ENGINEERS 5. THE INDEPENDENT PROFESSIONAL ENGINEER a. TYPES OF SELF-EMPLOYED ENGINEERS b. THE ALTERNATIVE TO THE SPECIAL REGIME FOR SELF-EMPLOYED WORKERS (RETA) 6. FROM BASIC TO DETAIL ENGINEERING a. PHASES OF INDUSTRIAL PROJECT PREPARATION b. BASIC PROJECT INFORMATION c. PERMITS AND LICENSES d. BASIC PROJECT ENGINEERING e. DETAIL ENGINEERING f. PURCHASE MANAGEMENT g. CONSTRUCTION SUPERVISION h. COMMISSIONING 7. ENGINEERING CONTRACTS a. CONTRACT TYPES b. FIDIC CONTRACTS 8. PUBLIC TENDERS a. CONCEPTS b. REQUIREMENTS c. TENDERS d. CONTRACT CONTENT e TENDER DOCUMENTS . PROPOSAL CONTENT 9. LOOKING AT THE COMPANY THROUGH AN ENGINEER'S EYES a. THE COMPANY'S ECOSYSTEM b. KNOWLEDGE ABOUT BUSINESS MANAGEMENT c. FROM MANAGER TO ENTREPRENEUR d. QUALITIES FOR SUCCESS e. WHAT TO DO AND WHAT NOT TO DO f. WHAT OTHERS HAVE ALREADY SAID |
| 203 | Degree in Industrial Technology Engineering | 2030146 | Advanced Robotics | Semester 1 | Control techniques for robots. Autonomous robotic systems. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210065 | Industrial Process Design II | Semester 2 | Design of electrical systems in industry; generation, transmission, and distribution of electrical energy. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550015 | Experimental Methods in Mechanical Engineering | Semester 1 | 1. DATA ACQUISITION Summary. Measurement equipment. Measurement chain. Uncertainty. Calibration. Data acquisition (cable connection, digital conversion, sample frequency, aliasing, leakage, filtering, windows). LabVIEW programming. Calibration of MEMS accelerometers and other applications. 2. INSTRUMENTATION AND EXTENSOMETRY Components in an instrumentation setup, experimental techniques and sensors in mechanical engineering. Extensometry. Application of wavelet transform in damage detection in structures. Machine testing and calibration. Displacement transducers. Extensometry setups in different equipment. Testing of a structure. 3. MACHINE TESTING Programming a servo hydraulic machine. Description of its components: hydraulic central and circuit, actuator, servo valve, controller, software, etc. Modes of testing and adjustment of parameters. Measurement equipment: LVDT, extensometer, load cell. Design of testing auxiliary equipment. Obtaining and processing the data. Testing of relaxation in a viscoelastic material. Creep compression test in a viscoelastic material. Cyclic dynamic testing in a cellular structure of a viscoelastic material (loss factor and dissipated energy). 4. CONCRETE TESTING Fracture mechanics applied to structural concrete. Normalized tests in concrete. Experimental determination of fracture behavior of structural concrete (fracture properties, size effect, applications). Influence of size and shape of specimens on the compression strength of concrete. Three point bend test controlling with CMOD. Determination of behavior curve stress-strain of concrete in cylindrical specimens. Work fracture test on a notch concrete specimen under RILEM procedure. Analysis of results. Determination of concrete properties. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210122 | Fundamentals and Simulation of Manufacturing Processes | Semester 2 | - Fundamentals of Forming Process Analysis: Plastic Forming; Machining; Non-Conventional Processes. - Design for Manufacturing and Assembly (DFMA). - Manufacturing Process Simulation. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550012 | Advanced Materials Mechanics | Semester 2 | PART 1: MECHANICS OF COMPOSITE MATERIALS (24H) BLOCK 1: ANISOTROPIC ELASTICITY (9h) Topic 1.1. Introduction. Topic 1.2. Formulation of the elastic problem in anisotropic materials. Topic 1.3. Basic elastic problems for a cylindrical solid. Topic 1.4. The Finite Element Method applied to anisotropic materials. Topic 1.5. Plane Elasticity and its applications. BLOCK 2: COMPOSITE MATERIALS (9h) Topic 2.1. Introduction. Topic 2.2. Mechanical behavior of a sheet. Topic 2.3. Mechanical characterization of a sheet Topic 2.4. Mechanical behavior of a laminate. Topic 2.5. Interlaminar stresses. Topic 2.6. Analysis of structural elements of composite material. BLOCK 3: FAILURE OF COMPOSITE MATERIALS (6h) Topic 3.1. Introduction. Failure mechanisms in composite materials. Topic 3.2. Failure criteria at the lamina level. Topic 3.3. Laminate failure. Degradation models. Topic 3.4. Micromechanical aspects of composite material failure. PART 2: NANOMECHANICS OF SOLIDS (16h) BLOCK 4: NANOMECHANICS OF SOLIDS (16h) Topic 4.1. Introduction to crystal lattices and their defects. Topic 4.2. Multiscale modeling of materials. Computational methods. Topic 4.3. Interatomic potentials. Topic 4.4. Energy stored in a crystal with defects. |
| 197 | Degree in Aerospace Engineering | 1970009 | Mathematics III | Semester 2 | Calculus in several variables. Ordinary differential equations. |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920042 | Advanced Fracture Mechanics and Fatigue | Semester 2 | BLOCK 1: Advanced Fracture Mechanics . Elasto-Plastic Fracture. Fracture in Quasi-Brittle Materials. BLOCK 2: Fatigue I. Fatigue behavior and growth modeling of small cracks. Fatigue under stress gradients in the small-crack regime. BLOCK 3: Fatigue II . Multiaxial Fatigue. Fretting Fatigue. Fatigue under Random Loading. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940035 | Vehicle Control | Semester 2 | 1. Introduction to Automotive Control 2. Modeling for Automotive Control 3. Propulsion System Control. Electric and Hybrid Vehicle Control 4. Dynamics Control: Traction, Stability, and Braking 5. Other Controls 6. Introduction to Intelligent Transportation Systems |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280060 | Electronics and Power Systems Control | Semester 2 | Chapter I. Introduction to electrical grids. Distribution and transmission networks. Chapter II. Voltage and frequency control in electrical power systems. Chapter III. Protection of electrical grids and electrical generators. Chapter IV. Introduction to power converters in energy applications. Chapter V. Electronic systems for the control of grid-connected converters. Chapter VI. Electronic systems for the integration of non-dispatchable renewable energies. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280008 | Graphic expression | TO | Thematic blocks Block I: Standardization Block II: Computer-Aided Drawing Block III: Representation Systems Blocks I + II (50% weight) Block III (50% weight) Thematic block I: STANDARDIZATION Topic 1. General principles of representation. Topic 2. Sections and cuts Topic 3. Dimensioning principles. Topic 4. Dimensional, geometric and surface specifications. Topic 5. Standardized machine elements. Topic 6. Fixed and removable joints. Topic 7. Analysis and interpretation of mechanical assemblies. Assembly and exploded view. Topic 8. Standardized symbology. Thematic block II: COMPUTER-ASSISTED DRAWING Topic 1. Introduction to CAD systems. Topic 2. Preparation and layout of flat representations. Topic 3. 3D part modeling. Thematic block III: REPRESENTATION SYSTEMS Topic 1. Introduction to Representation Systems. Topic 2. Fundamentals of the dihedral system. Direct method. Topic 3. Curves and technical surfaces Topic 4. Fundamentals of axonometric perspectives. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990022 | Environmental Quality Assessment | Semester 1 | - Sampling and analysis of environmental pollutants. - Automated methods for analyzing environmental pollutants. - Characterization and analysis of solid waste. |
| 203 | Degree in Industrial Technology Engineering | 2030133 | Thermal Installations in Industry | Semester 2 | 1. FUEL PREPARATION AND TRANSPORTATION Description of the different reception and storage facilities, transport networks, and auxiliary elements of a fuel facility. 2. HEAT TRANSFER FLUIDS Definition and fundamental characteristics of heat transfer fluids. Description of the main heat transfer fluids and associated thermal installations. 3. WATER VAPOR Description and properties of water vapor as a heat transfer fluid. Advantages of its use. Applications in the design and sensitivity analysis of steam operating parameters. 4. STEAM TRAPS Justification for the use of traps. Description of the main types of traps and their operating principles. Trap selection and sizing criteria. Trap line accessories. Trap installation diagrams. 5. DISTRIBUTION NETWORKS Fundamental characteristics of steam and condensate lines. Sizing criteria. Expansions. Line supports. 6. RECOVERY. REVAPORIZATION. Justification and uses of revaporization. Calculation of revaporization flow rate. Operation of a flash tank. Justification, calculation, and recovery of purges in the steam generator. 7. AUXILIARY EQUIPMENT Description of auxiliary equipment in a steam installation, such as: feed tanks, pressure degassers, and steam accumulators. |
| M143 | Master's Degree in Aeronautical Engineering | 51430024 | Advanced Air Traffic | Semester 1 | 1 Aeronautical easements. 2 Design of flight procedures. 3 SES and SESAR. 4 Validation of operational concepts in ATM. 5 Complexity in ATM. 6 Automation in ATM. 7 Integration of RPAS into the ATM system. --------------------------------------------------------------------------------------------------------- 1 Aeronautical easements. 2 Design of flight procedures. 3 SES and SESAR. 4 Validation of operational concepts in ATM. 5 Complexity in ATM. 6 Automation in ATM. 7 Operation of Unmanned Aircraft Systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560055 | Projects | Semester 1 | Methodology, organization and project management. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600011 | Robotics Projects | Semester 1 | V Design/Development Methodology Robotic Systems Architecture Techniques for Robotics Projects Selection of Hardware and Software Components |
| M195 | Double Master's Degree in Industrial Engineering and Chemical Engineering | 51950008 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| 199 | Degree in Telecommunications Technology Engineering | 1990018 | Fundamentals of Telematics Applications and Services | Semester 2 | Dynamic Web Application Programming. Dynamic Web Applications. Using Databases. |
| M228 | Master's Degree in Operation of Space Systems | 52280011 | Space Mission Design and Operations | Semester 2 | Mission design, Mission planning, Space vehicle configurations, Space project management, Risk management |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210115 | Distribution Systems Control | Semester 2 | BLOCK I Modeling and Machine Learning. I.1 Modeling and Simulation of Distribution Systems: I.2 Machine Learning Techniques: I.3 Estimation. Kalman Filter. I.4. Data Reconciliation and Fault Detection. BLOCK II Planning and Control of Distribution Systems II.1 Economic Planning. II.2. Constrained Control. BLOCK III. Numerical Optimization Techniques. III.1 Quadratic Problems. III.2 Gradential Optimal Methods. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990005 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280075 | Bioengineering | Semester 2 | - Basic concepts and applications in bioengineering. - Future development prospects. - Knowledge of the technological areas involved. - Medical applications. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560057 | Information systems | Semester 2 | The Information System in the Enterprise. Information Technologies in the Enterprise. Analysis and Design of Information Systems. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990011 | Engineering and Supervision of Chemical Plants | Semester 2 | Block I: Engineering project in a chemical plant Introduction to design. Strategies Organization and planning of a project Project planning and design software Documentation and drawings Permitting Industrial legalization Purchase management Block II: Regulations and regulations Storage of chemical products - Fuels Pressure equipment - Boilers Industrial insulation Legionella control and maintenance of cooling towers Fluid propulsion and solid transport equipment Industrial safety and hygiene Block III: Equipment and instrumentation design Boilers. Boiler water conditioning. Propulsion equipment Exchangers Cooling towers Absorption columns Storage tanks Instrumentation Valves Connections. Flanges. Fittings Block IV: Layout of a chemical plant Equipment implementation Piping Support Equipment assembly Block V: Supervision and analysis of chemical processes Estimation of investment and operation costs Data acquisition systems Industrial process control systems Start-up, operation and shutdown manuals Safety plans. Emergency response |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210028 | Energy Technology | Semester 1 | I. Energy Technology Overview. II. Heat Transfer Technology: Heat Exchange Equipment. III. Heat Transfer Fluids. IV. Refrigeration Production Technology. |
| 225 | Degree in Civil Engineering | 2250034 | Project and construction management | Semester 2 | Methodology, organization, and management of civil construction projects; regulations. Construction projects for land, water, and maritime transport infrastructure. Civil construction project management. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280052 | Electronic Systems for Automation | Semester 1 | Electronic systems for automation and control. Embedded systems. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830005 | Circular Economy and Sustainability | Semester 1 | Course Program Topic 1. Concepts of Sustainability and Circular Economy Topic 2. Sustainability and Environmental Management PRACTICAL CASE No. 1: Technical bases for the implementation of an integrated urban sustainable development process: the Local Agenda 21. Sustainability diagnosis, indicator system and action plan. Topic 3. Environmental Management Systems Topic 4. Economy and Environment PRACTICAL CASE No. 2: Strategy for plastics in a circular economy Topic 5. Circular Economy and Solid Waste PRACTICAL CASE No. 3: Advanced Landfill Mining (Enhanced Landfill Mining). STUDENT SEMINAR No. 1 Topic 6. Ecodesign and Ecolabel Topic 7. Quantification of Sustainability STUDENT SEMINAR No. 2 PRACTICAL CASE No. 4: The circular economy in the fertilizer production. European Commission Regulations CASE STUDY NO. 5: Critical Raw Materials and the Circular Economy (EU) CASE STUDY NO. 6: Implementation of the Deposit, Return and Refund System (DRRS) in the city of Seville/Andalusia/Spain. Combined example of circular economy and sustainability. STUDENT SEMINAR NO. 3 STUDENT SEMINAR NO. 4 STUDENT SEMINAR NO. 5 STUDENT SEMINAR NO. 6 NOTE: Throughout the course, an additional lecture given by a guest lecturer may be offered. |
| 225 | Degree in Civil Engineering | 2250024 | Roads | Semester 2 | Part I: Basic characteristics of the road system Topic 1. Road networks Topic 2. Activities of Highway Engineering Topic 3. Highway administrations Topic 4. Vehicles Topic 5. The driver and the pedestrian Part II: Highway planning. Traffic studies. Topic 6. Characteristic variables of road traffic Topic 7. Traffic studies Topic 8. Capacity and service levels in continuous circulation. Topic 9. Capacity and service levels at junctions Topic 10. Highway planning and planning Topic 11. Evaluation of alternatives Part III Geometric design Topic 12. Basic parameters of the layout Topic 13. The trajectory of vehicles Topic 14. Elements of the layout in plan Topic 15. Elements of the layout in elevation Topic 16. Coordination between the plan and the elevation Topic 17. Integration into the environment. Topic 18. The cross section Topic 19. Junctions, intersections and links. Part IV Road studies Topic 20. Inventories Topic 21. Scope of road studies Topic 22. Measurement and compensation of earthworks Topic 23. Operations prior to earthworks Part V Traffic planning, regulation and control Topic 24. Objectives and functions of road network operation. Topic 25. Elements supporting operation. Topic 26. Road aids. Incident management. Topic 27. Traffic management on high-capacity roads. Topic 28. Traffic management in urban areas. Part VI Road safety Topic 29. The problem of road traffic safety Topic 30. Collection and analysis of accident data Topic 31. Improving safety on service roads Topic 32. Road safety in road studies. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210070 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960042 | Dynamic systems modeling | Semester 1 | I) Continuous simulation. II) Discrete event simulation. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560029 | Theory of Machines and Mechanisms | Semester 1 | 1. Mobility analysis and topology of mechanisms. 2. Introduction to kinematic and dynamic analysis of mechanisms. 3. Application to mechanisms and machines. Synthesis of mechanisms. Machine elements. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210068 | Professional practice of Engineering | Semester 2 | Legislation, professional practice, IT tools, international project management. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560031 | Analysis and Prevention of Occupational Risks | Semester 2 | Legislation on risk prevention. Safety as a preventive technique. Hygienic risk. Ergonomic risk assessment. Prevention management. Industrial safety. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210142 | Electronic Systems for Renewable Energy Management | Semester 2 | Chapter I. Introduction to electronic systems for renewable energy management Chapter II. Wind energy Chapter III. Photovoltaic energy Chapter IV. FACTS systems, energy storage and electric vehicles |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560013 | Elasticity and Resistance of Materials | Semester 1 | TOPIC I BASIC CONCEPTS OF DEFORMABLE SOLIDS Introduction. Boundary and volume actions. Concept of stress. Cauchy's lemma. Equilibrium equations. Coordinate transformation. Principal stresses. Strain tensor. Compatibility equations. Tensile test. Generalized Hooke's law. Boundary conditions. Elastic problem. Saint-Venant's principle. Yield criterion. TOPIC II BASIC CONCEPTS FOR THE ANALYSIS OF BAR STRUCTURES Definition of bar. Actions on bars. Definition of internal stresses. Equilibrium equations TOPIC III TENSILE AND FLEXURE IN FULL SECTIONS Assumptions in bar models. Compatibility and behavior equations. Calculation of normal and tangential stresses. Recalculation of tangential stresses. Study of particular cases (axial, simple bending and compound bending). TOPIC IV TENSILE AND FLEXURE IN THIN-WALLED SECTIONS Definition of thin-walled profiles. Hypothesis. Calculation of stresses in open and closed sections. Shear stress center. Some considerations on symmetry. TOPIC V INTEGRATION OF THE BASIC EQUATIONS Introduction. Stress laws. Integration of the compatibility-behavior equations. Mohr's theorems. Free nodes and supports. Concept of degree of freedom. TOPIC VI STRUCTURAL CALCULATION METHODS. THE METHOD OF FORCES Use of symmetry in structures. Hyperstaticity and Isostaticity. The method of forces. TOPIC VII BUCKLING OF PRISMATIC MEMBERS Introduction. Euler's problem. General equation of the beam-column. Buckling of elements with imperfections. TOPIC VIII FREE TORSION Introduction. Kinematic hypotheses. Torsion in solid sections. Torsion in thin-walled profiles. |
| 199 | Degree in Telecommunications Technology Engineering | 1990017 | Structure and Protocols of Public Networks | Semester 2 | Introduction to telecommunications and telematics. Standardization and organizations. Layer models. The telephone network. Structure and signaling. IP telephony. Mobile cellular networks. Evolution of public networks. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210064 | Industrial Process Design I | Semester 1 | Analysis and design of chemical processes. Chemical plants. Design of hydraulic installations in industry. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280031 | Business Organization | Semester 2 | BLOCK I: General Accounting BLOCK II: Investments and Financing BLOCK III: Cost Accounting |
| 225 | Degree in Civil Engineering | 2250029 | Concrete Structures I | Semester 2 | |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040006 | Entrepreneurship | Semester 1 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560056 | Simulation of Industrial Systems | Semester 2 | Introduction to simulation. Simulation model building techniques. Specific content. Simulation software. Building and studying simulation models. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600012 | Wireless Sensor Networks | Semester 1 | A) THEORETICAL thematic blocks 1. INTRODUCTION TO WSNs 2. STANDARDS (with emphasis on 802.15.4) 3. HW FOR NODE DESIGN 4. OPERATING SYSTEMS 5. OTHER TOPICS B) PRACTICES 1. Network installation 2. Network programming 3. Network security |
| 197 | Degree in Aerospace Engineering | 1970042 | Airport Planning and Design | Semester 2 | - Regulations. - Site and access selection. - Design parameters. - Master Plan. - Easements and aeronautical aid systems. - Externalities. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210021 | Production Systems Management (OGSP, OGCS) | Semester 2 | Production Planning, Material Requirements Planning (MRP), Bottleneck Identification and Management (OPT), Just in Time: the Kanban Method (JIT) |
| 199 | Degree in Telecommunications Technology Engineering | 1990052 | Control engineering | Semester 1 | Analysis and synthesis of discrete-time feedback systems. Discrete-time internal description. Computer process control. |
| M164 | Master's Degree in Electrical Energy Systems | 51640002 | Quality and Efficiency of the Electricity Supply | Semester 2 | Topic 1. Power Supply Quality. Topic 2. Power Interruptions. Topic 3. Long-Term Voltage Variations. Topic 4. Voltage Imbalance. Topic 5. Harmonics. Topic 6. Voltage Fluctuations. Topic 7. Voltage Dips. Topic 8. Transient Overvoltages. Topic 9. Power Quality Measurement. Topic 10. International Power Quality Regulations. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210009 | Product Design in Industry | TO | Comprehensive design of industrial products. Design for manufacturing and assembly. Machine design and testing. Design of electrical, electronic, and control systems. |
| 203 | Degree in Industrial Technology Engineering | 2030088 | Thermal Installations in Buildings | Semester 1 | 1. Fundamentals of air conditioning installations 2. Air treatment 3. Indoor air quality 4. Thermal loads on the premises 7. Loads on the system 8. Free cooling and energy recovery 9. Air diffusion 10. Design of transport networks 11. Pumps and fans 12. Thermal generators 13. Air treatment equipment 14. Air conditioning project 15. DHW installations |
| 199 | Degree in Telecommunications Technology Engineering | 1990001 | Physical | Semester 1 | Mechanics, thermodynamics, waves and electricity and magnetism. |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990001 | Life cycle analysis | Semester 1 | Block 0: PROJECT Block 1. INTRODUCTION AND APPLICABLE REGULATIONS FOR LCA Block 2. LCA METHODOLOGIES. PHASES OF A LCA Block 3. TOOLS FOR LCA PREPARATION: DATABASES AND PROGRAMS Block 4. PRACTICAL CASES AND EXAMPLES OF LCAs |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560012 | Differential Equations | Semester 1 | Second-order linear differential equations. Laplace transform. Systems of linear differential equations. Stability and phase planes. Fourier series and boundary problems in ordinary differential equations. Method of separation of variables for solving partial differential equations. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280004 | Mathematics II | Semester 1 | Block 1. Functions and derivatives. Block 2. Integration. Block 3. Taylor polynomials and series. Block 4. Ordinary differential equations. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550005 | The Boundary Element Method | Semester 1 | BLOCK 1: INTRODUCTION TO THE BOUNDARY ELEMENT METHOD (BEM) (9h) Topic 1.1. Introduction to the basic concepts of the method. Topic 1.2. BEM approach to potential problems and its implementation in a computational code. Topic 1.3. Applications. BLOCK 2: BEM APPLIED TO POTENTIAL AND ELASTIC PROBLEMS (15.5h) Topic 2.1. Calculation of singular integrals. Topic 2.2. The Symmetric Galerkin BEM. Topic 2.3. BEM approach to static elastic problems and its implementation in a computational code. Topic 2.4. Applications. BLOCK 3: BEM APPLIED TO ELASTIC WAVE PROPAGATION PROBLEMS (15.5h) Topic 3.1. Wave propagation. Topic 3.2. 2D Formulation of the FEC in the Frequency Domain. Section 3.3. 3D Formulation of the FEC in the Frequency Domain. Section 3.4. 3D Formulation of the FEC in the Time Domain. Section 3.5. Applications. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560011 | Automatic control | Semester 1 | - System modeling and identification. - Time-response analysis and stability analysis of linear systems. - Principles and techniques of system and process control. - Design and implementation of basic control systems. - Introduction to Logic Automation. |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320006 | Space Vehicle Dynamics | Semester 1 | Kinematics and dynamics of a spacecraft's attitude. Spacecraft attitude control and estimation. Advanced orbital mechanics. Orbit optimization, control, and estimation techniques. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900007 | Transport and Urban Services Complements | Semester 1 | BLOCK 1 TRANSPORTATION COMPLEMENTS The urban, interurban and regional transport system. Mobility and flows. Demand analysis. Modality and modal split. Networks and assignment. Modeling and simulation. Demand and flow estimation and forecasting. Costs, benefits, financing and pricing. Externalities. Project and investment evaluation. BLOCK 2 URBAN SERVICES COMPLEMENTS Water supply and distribution. Distribution networks. Water treatment for supply. Collector and sanitation network projects. Urban water purification. Urban water cycle management. Design and management of urban waste collection systems. Calculation. Design and operation of facilities for urban waste management. |
| 225 | Degree in Civil Engineering | 2250075 | Geographic Information Systems | Semester 2 | Theoretical Program: Topic 1: GIS Concept Topic 2: Databases Topic 3: Geographic data and SDI Services Topic 4: Vector geographic information systems Topic 5: Geoprocessing and topology Topic 6: Network model Topic 7: Raster geographic information systems Topic 8: Digital terrain models and LiDAR Topic 9: Inspire models used in civil engineering Practical program: Practice 1.1 Collection, dumping and management of field data in QGIS Practice 1.2 Terrestrial reference systems and cartographic projections Practice 2 Creation and management of databases Practice 3 Query of SDI services Practice 4.1 Derived geometry Practice 4.2 Maps Practice 5.1 Geoprocessing Practice 5.2 Topology Practice 6 Creation and management of a network model Practice 7 Raster operations Practice 8.1 Digital elevation models Practice 8.2 LiDAR data management Practice 9 Other utilities |
| 208 | Degree in Chemical Engineering | 2080037 | Chemical Reactors | Semester 2 | Operations controlled by reaction kinetics and rate, thermodynamics and chemical reaction. |
| M228 | Master's Degree in Operation of Space Systems | 52280008 | Satellite Electronic Systems | Semester 1 | Instrument types; instrument models; Earth observation sensors; scientific missions and instrumentation; payload requirements analysis and design; concept of operations |
| 199 | Degree in Telecommunications Technology Engineering | 1990074 | Satellite Communications | Semester 2 | Orbits and launch vehicles. Space and control segment. Ground stations and mobile terminals. Link analysis. Modulation, multiplexing, and multiple access techniques. Satellite networks. Operating and commercial systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560016 | Fluid mechanics | Semester 2 | Fluid flow of interest in engineering. General differential equations (Navier-Stokes), integrals, and dimensional analysis. Fluid statics. Incompressible flow of viscous and ideal fluids. Fluid dynamics around solid bodies. Fundamentals of boundary layer flow and turbulence. Compressible and incompressible unidirectional motions. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210047 | Hydraulic and Marine Energy | Semester 1 | Hydraulic Energy Block I: Overview of hydraulic energy use and its components. II: Energy analysis of hydraulic energy use. III: Turbine analysis. Marine Energy Block IV: Overview of energy use of marine resources. V: Energy analysis of marine resources. |
| M181 | Master's Degree in Chemical Engineering | 51810012 | Waste Engineering | Semester 1 | Domestic waste: collection and management. Characterization and treatment of hazardous waste. Biological treatments. Thermal treatment. Waste landfill. Radioactive waste. Soil reclamation. Topic 1. Introduction. Waste. General problems. Topic 2. Legislation. Characterization of domestic and commercial waste. Management and characterization of hazardous waste. Topic 3. Urban waste management and collection systems. Recycling. Topic 4. Urban waste processing and separation technologies . Topic 5. Biological waste treatment. Composting. Anaerobic digestion. Topic 6. Thermal treatment of waste. Topic 7. Physicochemical treatment of hazardous waste. Topic 8. Stabilization-solidification treatments of hazardous waste. Topic 9. Waste landfill. Topic 10. Radioactive waste management. Topic 11. Consumer goods waste management. |
| 199 | Degree in Telecommunications Technology Engineering | 1990079 | Holography and 3D Visualization | Semester 2 | Fundamentals and characterization of optical technologies. Stereoscopy and 3D vision systems. 3D image capture and recording systems. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550011 | Advanced Fracture Mechanics and Fatigue | Semester 2 | BLOCK 1: Advanced Fracture Mechanics . Elasto-Plastic Fracture. Fracture in Quasi-Brittle Materials. BLOCK 2: Fatigue I. Fatigue behavior and growth modeling of small cracks. Fatigue under stress gradients in the small-crack regime. BLOCK 3: Fatigue II . Multiaxial Fatigue. Fretting Fatigue. Fatigue under Random Loading. |
| 197 | Degree in Aerospace Engineering | 1970003 | Company | Semester 1 | Adequate understanding of the concept of business, the institutional and legal framework of business. Business organization and management. Air transport economics. |
| 225 | Degree in Civil Engineering | 2250006 | Computing | Semester 2 | Computer fundamentals. Algorithms. Programming. Introduction to operating systems, databases, and software with applications in engineering. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970048 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| 225 | Degree in Civil Engineering | 2250037 | Hydraulic uses | Semester 1 | Topic 1. Basic Concepts of Hydroelectric Development General Concepts. Main components of an electric jump. Classification of hydroelectric jumps. Basic development schemes. General Considerations. Power of a Jump. Productivity of a jump. Electricity market. Topic 2. Definition and sizing of elements Intakes. Chimneys and water hammer. Mechanical calculation of pipelines. General Development Design. Topic 3. Turbines. Generalities. Power and General Equation. Similarity. Selection. Topic 4. Basic Issues of Irrigation Physical characteristics of the soil. Factors influencing irrigation. Water storage in the soil. Water requirements of crops. Drainage techniques Topic 5. Gravity irrigation Runoff irrigation. Flood irrigation. Infiltration irrigation Topic 6. Sprinkler Systems Sprinklers. Conventional systems. Non-conventional systems. Hydraulic characteristics of sprinklers. Sprinkler distribution in conventional systems. Irrigation uniformity and efficiency. Distribution of lateral branches and pipes. Topic 7. Drip Systems . System components. Irrigation uniformity and efficiency. Amount of water required. Installation diagram and sizing criteria. Micro-sprinkler. Topic 8. Collective Networks . Layout guidelines. Flow calculations. Operating systems for network sizing. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210034 | Systems Modeling and Optimization (OGSP, OGCS) | Semester 2 | Decision techniques. Nonlinear optimization. Integer programming. Optimization model building. Approximate optimization methods. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560003 | Company | Semester 2 | Concept of business, institutional and legal framework of business. Economic environment of business. Business organization and management |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210079 | Forensic Engineering: Selection and Characterization of Materials | Semester 2 | Failure analysis. Post-mortem studies. Advanced study techniques: Electron microscopy, XRD, chemical analysis, etc. Non-destructive testing. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210107 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| M165 | Master's Degree in Thermal Energy Systems | 51650003 | Diagnosis, Testing and Certification of Power Production Systems | Semester 1 | BLOCK I: ENERGY FRAMEWORK OF POWER PLANTS POWER PLANT ELEMENTS POWER PLANT PERFORMANCE ASSESSMENT: REFERENCE CHANGE AND DEGRADATION APPLICABLE REGULATIONS BLOCK II: GAS TURBINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES GAS TURBINES: FAILURE TYPOLOGY STEAM TURBINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES STEAM TURBINES: FAILURE TYPOLOGY ALTERNATIVE ENGINES: ENGINE MODEL WITH REAL FLUIDS AND THERMAL MACHINES ALTERNATIVE ENGINES: FAILURE TYPOLOGY BLOCK III: TOOLS FOR THE IDENTIFICATION/QUANTIFICATION OF DEGRADATION IN WORK CYCLES |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550016 | Advanced Mathematical Methods in Engineering | Semester 1 | Numerical methods for solving problems involving ordinary differential equations. Stability theory of dynamical systems. Long-term and global behavior. Continuation methods for ordinary differential equations. |
| 208 | Degree in Chemical Engineering | 2080052 | Materials technology | Semester 2 | Block I. Introduction. Material selection criteria. Processing-structure-properties relationship. General considerations: material families, processing types, and service conditions. Examples of practical application cases (there is no ideal material). Block II. Metallic alloys and their processing. Carbon steels and their heat treatments (mass and surface). Weakly alloyed, high-alloy, stainless, and tool steels. Metals with cryogenic applications and used at high temperatures. Ferrous castings. Fe-Gr versus Fe-Fe3C equilibrium diagram. Influence of the type of matrix and/or graphite on the properties of ferrous castings. Non-ferrous metallic materials, properties and applications: copper and its alloys; aluminum and its alloys; magnesium and its alloys. Examples of metallic superalloys. Molding and continuous casting. Suitability for molding. Physical and chemical heterogeneities. Plastic deformation (cold, warm, and hot drawing). Metal welding. Fusion and solid-state welding. Brazing and soldering. Metallurgical aspects and defects inherent in the welding process and the heat-affected zone. Conventional powder metallurgical processing (mechanical grinding, mixing, pressing, and sintering). Modern trends in powder metallurgy: MIM, directed freezing, electrical sintering, laser sintering or fusion, etc. Block III. Ceramic materials, processing, and applications. Glass, raw materials, and manufacturing processes. Relationship between properties and applications. Traditional ceramics and cements, raw materials, manufacturing process steps, properties, and applications. Advanced, functional, and structural ceramics. Applications and properties. Block IV. Polymers and their processing. Thermoplastics, thermosets, elastomers, and fibers. Influence of temperature and mechanical stress. Applications. Differences between polymers and commercial plastics, relationship between additives and material properties. Conventional polymer forming (extrusion, injection molding, thermoforming, etc.). More complex or advanced processes: co-extrusion, co-injection, and additive manufacturing (3D printing: FDM, FFF, etc.). Adhesive bonding or welding of plastic parts. Recycling and/or reuse of plastics. Block V. Composite materials and their processing. Types of composite materials based on their matrix (metal, ceramic, or polymer). Types of reinforcements (particles or fibers). Manufacturing processes, typical manufacturing defects, influence of reinforcement properties and compatibility with the matrix on the in-service behavior of the composite material. Examples of composite materials and their uses. Block VI. In-service behavior of parts, components, or structures. Mechanical behavior (tensile, compression, torsion, bending, and fatigue), concept of damage tolerance. Fracture resistance of brittle materials, application of Weibull statistics, concepts of failure probability. Design criteria: small elastic strains, yield strength, plastic collapse, fracture toughness, and failure analysis diagram. Hardening and fracture toughness increase mechanisms (R-curve). SN curves and Goodman diagram. Fatigue limit, strength, and sensitivity. Damage tolerance (kinetics of large crack growth propagation by phatic forces - Paris-Erdogan Law). Influence of notch sensitivity, surface finish, temperature, and environmental conditions. Thermomechanical behavior: viscoelasticity, thermocreep, and stress relaxation phenomena. Mechanisms responsible for creep, influence of grain size. Degradation of structural components under contact stresses (friction and wear). Mechanisms and types of wear. Wear prevention: lubrication and surface modification treatments. Degradation of polymers and ceramics, as well as corrosion of metallic materials in aggressive media. Mechanisms, types and actions for the prevention of corrosion phenomena. Practicals P1: In-Service Behaviour (2.5 h) Metallography of metals Effect of temperature on in-service behaviour: heat treatments, thermal shock Determination of mechanical properties: microhardness, fracture toughness¿ P2: Forensic Powder Metallurgy (2.5 h) Fundamentals of the manufacturing process for parts using metal powders: powder characterization, mixing, compaction and study of manufactured parts (porosity, image analysis) Comparison with other manufacturing techniques. P3: Forensic Engineering (2.5 h) Non-destructive testing (NDT): Physical principle, experimental procedure, as well as advantages and disadvantages of the most common techniques used to evaluate surface and/or internal defects. Failure analysis: principles and methodology of forensic engineering; fault diagnosis. Analysis of real cases of failure in service. Note: each professor, in addition to the generic real cases presented, may comment on some according to their scientific-technical and/or industrial experience |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960035 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 203 | Degree in Industrial Technology Engineering | 2030172 | Measurement and Control of Environmental Pollution (QU) | Semester 1 | - Environmental pollutants, types, and effects. - Sampling and analysis of pollutants. - Automatic equipment for pollutant analysis. - Waste characterization. - Environmental legislation. |
| 197 | Degree in Aerospace Engineering | 1970016 | Automatic control | Semester 2 | Fundamentals of automatic control. Analysis of dynamical systems in the time domain. Analysis of linear models of dynamical systems in the frequency domain. Stability. Control methods. Computer control. Basic principles of flight control and automation. |
| 197 | Degree in Aerospace Engineering | 1970044 | Electronic Communication Systems | Semester 2 | Analog and digital communications systems. Electronic radio and satellite communications systems. On-board optical communications. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560024 | Manufacturing technology | Semester 2 | 1. Introduction to manufacturing 2. Measurement, verification and quality control techniques 3. Metal casting processes 4. Plastic forming of metals 5. Machining processes 6. Polymeric and composite materials 7. Joining processes 8. Manufacturing and production systems 9. Non-conventional manufacturing processes 10. Introduction to additive manufacturing |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920043 | Advanced Materials Mechanics | Semester 2 | PART 1: MECHANICS OF COMPOSITE MATERIALS (24H) BLOCK 1: ANISOTROPIC ELASTICITY (9h) Topic 1.1. Introduction. Topic 1.2. Formulation of the elastic problem in anisotropic materials. Topic 1.3. Basic elastic problems for a cylindrical solid. Topic 1.4. The Finite Element Method applied to anisotropic materials. Topic 1.5. Plane Elasticity and its applications. BLOCK 2: COMPOSITE MATERIALS (9h) Topic 2.1. Introduction. Topic 2.2. Mechanical behavior of a sheet. Topic 2.3. Mechanical characterization of a sheet Topic 2.4. Mechanical behavior of a laminate. Topic 2.5. Interlaminar stresses. Topic 2.6. Analysis of structural elements of composite material. BLOCK 3: FAILURE OF COMPOSITE MATERIALS (6h) Topic 3.1. Introduction. Failure mechanisms in composite materials. Topic 3.2. Failure criteria at the lamina level. Topic 3.3. Laminate failure. Degradation models. Topic 3.4. Micromechanical aspects of composite material failure. PART 2: NANOMECHANICS OF SOLIDS (16h) BLOCK 4: NANOMECHANICS OF SOLIDS (16h) Topic 4.1. Introduction to crystal lattices and their defects. Topic 4.2. Multiscale modeling of materials. Computational methods. Topic 4.3. Interatomic potentials. Topic 4.4. Energy stored in a crystal with defects. |
| 225 | Degree in Civil Engineering | 2250004 | Physics I | Semester 1 | Basics of metrology. Vector algebra. Mechanics. Oscillations. Waves. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940044 | Mobile and Service Robotics | Semester 1 | INTRODUCTION MOBILE ROBOTICS PLANNING POSITION ESTIMATION SERVICE APPLICATIONS |
| 225 | Degree in Civil Engineering | 2250026 | Hydraulic Infrastructures | Semester 1 | Hydraulic regulation works Gates, spillways, weirs and drains Pressure pipes Canals Pumping stations Irrigation |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980036 | Design, Operation and Maintenance of Gas Power Plants | Semester 1 | I Gas turbine technology 1. Gas turbine cycles. 2. Main components: turbocharger, combustion chamber, turbine. 3. Technological development of gas turbines. Effect of cooling on engine performance. 4. Matching (turbine-compressor coupling). 5. Off-design operation. 6. Performance deterioration. II Combined cycles 1. Thermodynamic foundations of combined cycles 2. Exhaust gas energy recovery 3. Cycles with steam production at one pressure. 4. Cycles with steam production at several pressures. 5. Other components of combined cycles. 6. Partial load operation 7. State of the art and development lines. III Emissions IV Operation and maintenance |
| M165 | Master's Degree in Thermal Energy Systems | 51650005 | Design, Operation and Maintenance of Gas Power Plants | Semester 1 | I Gas turbine technology 1. Gas turbine cycles. 2. Main components: turbocharger, combustion chamber, turbine. 3. Technological development of gas turbines. Effect of cooling on engine performance. 4. Matching (turbine-compressor coupling). 5. Off-design operation. 6. Performance deterioration. II Combined cycles 1. Thermodynamic foundations of combined cycles 2. Exhaust gas energy recovery 3. Cycles with steam production at one pressure. 4. Cycles with steam production at several pressures. 5. Other components of combined cycles. 6. Partial load operation 7. State of the art and development lines. III Emissions IV Operation and maintenance |
| 208 | Degree in Chemical Engineering | 2080017 | Fundamentals of Materials Science | Semester 2 | 1. INTRODUCTION TO MATERIALS SCIENCE 2. ATOMIC SCALE OF MATERIALS: ORDER AND DISORDER 2.1 Intimate structure of materials 2.2 The atomic scale of metallic materials 2.3 The atomic scale of ceramic materials 2.4 The atomic scale of molecular materials 2.5 The atomic scale of polymeric materials 2.6 Crystalline imperfections 3. MICROSCOPIC SCALE OF MATERIALS: PHASE TRANSFORMATIONS AND MICROSTRUCTURE 3.1 Phase transformations 3.2 Phase diagrams in equilibrium 3.3 Non-equilibrium aspects 4. MACROSCOPIC SCALE OF MATERIALS: MACROSCOPIC PROPERTIES 4.1 Mechanical properties and behavior in service of materials 4.2 Electrical properties of materials 4.3 Thermal properties of materials 5. LABORATORY PRACTICES 5.1. Crystal structures (1.5 hours). 5.2. Metallographic preparation (1.5 hours) . 5.3. Basic metallography of steels (1.5 hours). 5.4. Metallography of non-ferrous metals (1.5 hours). 5.5. Hardness measurement (1.5 hours). |
| 208 | Degree in Chemical Engineering | 2080013 | Mathematics expansion | Semester 1 | Knowledge of advanced aspects of Mathematical Analysis and its applications: differential equations, Laplace transform, systems of differential equations, Fourier series, and partial differential equations. |
| 197 | Degree in Aerospace Engineering | 1970066 | Aircraft Calculation | Semester 2 | Aircraft Configuration. Aircraft Design. Airworthiness Standards. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940043 | Wireless Sensor Networks | Semester 1 | A) THEORETICAL thematic blocks 1. INTRODUCTION TO WSNs 2. STANDARDS (with emphasis on 802.15.4) 3. HW FOR NODE DESIGN 4. OPERATING SYSTEMS 5. OTHER TOPICS B) PRACTICES 1. Network installation 2. Network programming 3. Network security |
| 199 | Degree in Telecommunications Technology Engineering | 1990078 | Consumer electronics | Semester 2 | Laptops, audio and video playback, digital cameras, video game consoles, television and digital audio, mobile phones, PDAs. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040016 | Healthcare Services Architectures | Semester 1 | Characterization of services in the healthcare environment Integration and interoperability of services in the healthcare environment Healthcare software engineering projects |
| 225 | Degree in Civil Engineering | 2250002 | Statistics and Operations Research | Semester 2 | Statistics and optimization. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900014 | Sanitary Engineering | Semester 1 | Water management cycle. Drinking water treatment plants (DWTPs) and urban wastewater treatment plants (WWTPs): sizing and operation. Supply and sanitation systems |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920041 | Advanced Fluid Mechanics | Semester 2 | I. Review of the Navier-Stokes equations. II. Computational fluid dynamics (CFD) III. Application of CFD to engineering flows REFERENCES A. BARRERO and M. PEREZ-SABORID, Introduction to Fluid Mechanics and its Applications, Ed. McGraw-Hill, 2005. F. M. WHITE, Fluid Mechanics, Ed. McGraw-Hill, 2004. G. K. BATCHELOR, An Introduction to Fluid Dynamics, Ed. Cambridge University Press, 1967. LANDAU and LIFSHITZ, Fluid Mechanics, Pergamon Press. SCHLICHTING, Boundary Layer Theory, Ed. McGraw-Hill. (There is a Spanish version 'Boundary Layer Theory' in the ETSI Library) |
| 199 | Degree in Telecommunications Technology Engineering | 1990011 | Physics Extension | Semester 1 | 1. Fields and waves. 2. Numerical methods in electromagnetism. 3. Electromagnetic waves and principles of optics. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960038 | Management Information Systems | Semester 1 | The course content will be tailored to the following descriptors: - Search, manage, and analyze relevant information for decision-making, as well as understand and use business information systems to support decision-making in the field of Industrial Organization. |
| 203 | Degree in Industrial Technology Engineering | 2030105 | Electrical substations | Semester 1 | HV switchgear and installations, substations, protection of HV installations and lines, insulation coordination, grounding networks. |
| M196 | Double MU in Industrial Engineering and Industrial Organization and Business Management | 51960036 | Integrated Operations Management in Production and Service Systems | Semester 1 | I) Advanced production design and planning techniques. II) Advanced production scheduling and control techniques. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210017 | Geotechnics and Foundations (DECI) | Semester 2 | Land survey. Soil mechanics. Foundation design. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560041 | Automation and Robotics Laboratory | Semester 2 | Flexible manufacturing cell automation. Robot programming. |
| 199 | Degree in Telecommunications Technology Engineering | 1990035 | Fundamentals of Image Processing | Semester 2 | Two-dimensional transforms. Color spaces. Color application. Image enhancement and segmentation techniques. Image compression. Image formats. |
| 225 | Degree in Civil Engineering | 2250003 | Graphic expression | TO | Part 1: STANDARDIZATION 1.1 Standardized dihedral representation systems 1.2 Cuts and sections 1.3 General dimensioning principles 1.4 Interpretation of plans, especially those representations related to construction in general and civil engineering in particular Part 2: DESCRIPTIVE GEOMETRY 2.1 Dihedral System 2.1.1 Brief review of the content that students should have learned in high school: Membership relationships Parallelism and perpendicularity Drops Changes of plane Distances and angles 2.2 Bounded System 2.2.1 Point, line and plane. Slope of the line, module or interval. 2.2.2 Intersections 2.2.3 Parallelism, perpendicularity and distances 2.2.4 Application of the dimensioned drawing system to the resolution of building roofs, pipes and drains. Part 3: TOPOGRAPHIC DRAWING 3.1 Representation of the Earth's surface. Contour lines. Landforms. Determining the line of maximum slope on a piece of land. Determining the line of constant slope on a piece of land. Profiles. Flat section of a piece of land. 3.2 Grading and ponds 3.3 Geometric design of linear works. Previous geometric concepts: cuttings and fills. Natural slope or gradient of a soil. Slope cone. Surfaces of equal slope: slope planes; conical slope surfaces; helical slope surfaces. Graphical resolution of roads and grading using the slope surface method. Horizontal roads with a straight layout. Horizontal roads with a circular layout. Straight layout and constant gradient roads. Mixtilinear layout and constant gradient roads: slope cone method; helical surface method. 3.4 Longitudinal and transverse profiles 3.5 Calculation of earthworks Part 4: MANAGEMENT AND LEARNING OF SPECIFIC COMPUTER SOFTWARE FOR DESIGN AND DOCUMENTATION OF CIVIL ENGINEERING PROJECTS 4.1 Resolution and obtaining of plans of explanatory works through computer applications. 4.2 Resolution and obtaining of plans of linear works through computer applications: Profiles. 4.3 Resolution and obtaining of plans of linear works through computer applications: Plan, transverse profiles and earthworks. 4.4 Resolution and obtaining of plans of irrigation ponds through computer applications |
| M146 | Master's Degree in Industrial Engineering | 51460030 | Project and Integrated Works Management in Industrial Engineering | Semester 2 | PART 1: Design of industrial buildings and facilities. 1. Introduction to the concept of an Engineering Project. 2. Definition of the scope of the project. Contents of the Industrial Project. 3. Basic concepts of industrial building design. 4. Basic concepts of industrial facility design. (Water supply, evacuation and sanitation, fire protection, compressed air, lighting, electricity supply, etc.) PART 2: Urban planning in industrial engineering and urbanization and services projects in industrial and business parks and estates. 1. Introduction to Urban Planning. 2. Legislation 3. Location of industries . 4. Subdivision of estates . 5. Industrial estates. Services . 6. Evacuation and Emergency Plans . PART 3: Integrated construction management. 1. Organization of works. 2. Contracts . 3. Planning and control of works. 4. Management of purchases and subcontracts . 5. Execution of works. 6. Safety on construction sites. |
| 199 | Degree in Telecommunications Technology Engineering | 1990067 | Digital Signal Processing in Communications | Semester 1 | Synchronization. Encoders and decoders. Equalization. Linear prediction. Wiener filter. Software-defined radio. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630011 | Advanced Quantitative Management Methods | Semester 1 | The subject consists of two different modules: 1) Analysis of networks and complex systems 2) Cooperative games |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210131 | Microsystems and Nanotechnologies | Semester 2 | THEMATIC BLOCKS 1. INTRODUCTION TO MICROSYSTEMS. 2. APPLICATIONS OF MICROSYSTEMS. 3. DESIGN AND MANUFACTURING A MICROSYSTEM. 4. INTRODUCTION TO NANOTECHNOLOGY. |
| 199 | Degree in Telecommunications Technology Engineering | 1990058 | Telecommunication Systems Projects | Semester 1 | Project Development Methodology Legislation The College. Approvals Frequency Reservation. CNAF Certification. Calculating Reference Volume in Radiant Systems Staking Out. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560001 | Linear Algebra | Semester 1 | Conics and quadrics. Complex numbers. Systems of linear equations and matrices. Gaussian elimination. The vector space Rn. Orthogonality. Least squares. Eigenvalues and eigenvectors. Quadratic forms |
| 197 | Degree in Aerospace Engineering | 1970058 | Orbital Mechanics and Space Vehicles | Semester 1 | Orbital Mechanics. Space Vehicle Dynamics. Space Vehicle Systems. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560026 | Electrical technology | TO | I. DESCRIPTION OF ELECTRICAL SYSTEMS. II. THE TRANSFORMER. III. THE INDUCTION MOTOR. IV. SHORT-CIRCUIT CALCULATION V. LOW-VOLTAGE ELECTRICAL INSTALLATIONS. VI. MEDIUM-VOLTAGE DISTRIBUTION VII. HIGH-VOLTAGE TRANSPORTATION VIII. ELECTRICAL POWER GENERATION |
| M228 | Master's Degree in Operation of Space Systems | 52280010 | Space Environment | Semester 1 | Solar systems; Magnetosphere; low orbit environment; plasmas; effects on materials; effects on humans |
| M199 | Double Master's Degree in Chemical Engineering and Environmental Engineering | 51990004 | Integrated Design of Processes and Products | Semester 1 | The course consists of two thematic blocks: 1. Process Synthesis Block. This block focuses primarily on the Hierarchical Method for Synthesis of continuous chemical processes. It includes the analysis and design of reaction and separation systems, as well as the recirculation system between the two. 2. Process Integration Block. This block includes methods and techniques based on pinch analysis to achieve energy-efficient design of chemical processes. It addresses the design of heat exchange networks with criteria of maximum energy recovery and economic cost. |
| M183 | Master's Degree in Environmental Engineering (2018) | 51830008 | Environmental Quality Assessment | Semester 1 | - Sampling and analysis of environmental pollutants. - Automated methods for analyzing environmental pollutants. - Characterization and analysis of solid waste. |
| M181 | Master's Degree in Chemical Engineering | 51810023 | Energy Technology | Semester 1 | BLOCK 1 - REFRIGERATION TECHNOLOGY 1.01 Introduction 1.02 Physical and Thermodynamic Bases 1.03 Simple mechanical compression cycle 1.04 Multiple compression 1.05 Compressor technology 1.06 Evaporator and condenser technology 1.07 Accessories and refrigerants BLOCK 2 - INDUSTRIAL THERMAL INSTALLATIONS 2.01 Heat transfer fluids 2.02 Water vapor 2.03 Steam traps 2.04 Flash evaporation recovery 2.05 Distribution networks 2.06 Auxiliary equipment |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270050 | Production Programming and Control | Semester 1 | Production control systems. Bottlenecks. Operation scheduling. Sequencing. Operation rescheduling. Lean manufacturing. Just-in-time production systems. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270055 | Integrated Production Systems | Semester 1 | Computer-aided manufacturing. Flexible manufacturing systems. Computer-integrated manufacturing. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900042 | Communication Techniques and Professional Skills | Semester 2 | Effective communication strategies in a technical context, development of soft skills |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270011 | Business Management | Semester 1 | DESCRIPTORS: - Business Administration. - General Accounting. - Financial Statements. - Management Control Techniques. - Investment Analysis. THEMATIC BLOCKS: BLOCK 1: FUNDAMENTALS OF THE COMPANY CONCEPT BLOCK 2: ECONOMIC ANALYSIS OF THE COMPANY BLOCK 3: COST AND MANAGEMENT ACCOUNTING BLOCK 4: ANALYSIS OF INVESTMENTS AND FINANCING OPERATIONS |
| 208 | Degree in Chemical Engineering | 2080046 | Business Organization and Management | Semester 1 | BLOCK 1. Analysis of the company's situation based on the financial statements. BLOCK 2. Investment and financing analysis. BLOCK 3. Cost accounting. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210132 | Modeling and Optimization of Management Problems | Semester 2 | Subject descriptors: - Operations research. - Artificial intelligence applied to industrial management problems. - Optimization in Project Management. Thematic blocks: BLOCK 1: Modeling management problems. BLOCK 2: Optimization of management problems and project management. BLOCK 3: Artificial intelligence applied to industrial management problems. BLOCK 4: Project development and management. Coding of models and resolution methods. |
| M181 | Master's Degree in Chemical Engineering | 51810006 | Integrated Design of Processes and Products | Semester 1 | The course consists of two thematic blocks: 1. Process Synthesis Block. This block focuses primarily on the Hierarchical Method for Synthesis of continuous chemical processes. It includes the analysis and design of reaction and separation systems, as well as the recirculation system between the two. 2. Process Integration Block. This block includes methods and techniques based on pinch analysis to achieve energy-efficient design of chemical processes. It addresses the design of heat exchange networks with criteria of maximum energy recovery and economic cost. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900026 | Tunnels and Deep Excavations | Semester 1 | Topic 1: Introduction and history of tunnels - History of tunnel construction. Chronology - Tunnels in Spain - Tunnel elements - Site planning and reconnaissance - Examples Topic 2: Basis of geology and geotechnics for tunnel design and construction - Influence of geological conditions. Structural instability - Matrix rock and rock mass. Tests. Mohr-Coulomb and Hoek-Brown criteria. - Discontinuities. General aspects. Patton and Barton-Choubey failure criteria - Geomechanical classifications and their application to tunnel design Topic 3: Stresses and "In situ" techniques - In situ stress state - Importance. Stress states around tunnels and excavations. Elastic solutions - In situ stress measurement. In situ stress release. Stress restoration. Hydraulic fracturing. Stress changes in inclusions Topic 4: Tunnel-support interaction -Definition and hypothesis. Characteristic curves and confinement -Plane deformation (circular tunnel). Mohr-Coulomb elastoplastic model. Undrained case. Hoek-Brown elastoplastic model -Spherical cavity. Mohr-Coulomb elastoplastic model. Undrained case. Hoek-Brown elastoplastic model -Support curves -Interaction in lining with concrete, steel trusses and bolts -Deformation prior to the installation of the support. Use of the convergence-confinement method Topic 5: Drainage and waterproofing of tunnels -General aspects. Water flow into the tunnel. Transient and steady state -Effect of flow on mechanical conditions. Characteristic curves -Water protection during construction -Water protection during operation -Shotcrete lining, metal trusses, bolts, umbrellas, injections, etc. Topic 6. Rock tunnel construction -Excavability criteria. -Excavation methods. Tunnel boring machines (moles), roadheaders, and hydraulic hammer -Cutting tools -New Austrian Method (NMA). -Stability of manholes. -Examples Topic 7: Tunnel face stability -Introduction -Solutions based on plastic collapse theorems. -Analysis under undrained (2D) and drained (3D) conditions -Support measures. -Real case: Failure of tunnel faces Topic 8: Soil tunnel construction -Excavation methods -Traditional construction methods. Belgian. German. Example: Subway construction -Integral machines. EPB shields. Universal machines - Slopes excavated in soil. Cut-over - Movements induced by tunnel boring machines. - Lining design Topic 9: Tunnel-induced movements - Surface settlements. Empirical methods. Ground loss - Displacements around tunnels. Theoretical and semi-empirical methods. - Methods for estimating movements due to tunnel construction with shields - Practical cases or examples. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210027 | Environmental Technology | Semester 1 | Characteristics of solid waste, water discharges, and atmospheric emissions and their effects on the environment. Environmental legislation. Pollution prevention. Treatment technologies and characteristics of pollutant purification processes. |
| M164 | Master's Degree in Electrical Energy Systems | 51640009 | Operation and Control of Electrical Systems | Semester 1 | A. Control center architecture B. State estimation in electrical networks C. Frequency and voltage control D. Short and long-term operation planning E. Maintenance of electrical installations F. Project management of electrical installations |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210044 | Automatic Technology | Semester 2 | Introduction to automation Design and implementation of logical automation logic controllers (PLC) Programming of programmable logic controllers |
| M164 | Master's Degree in Electrical Energy Systems | 51640016 | Transients in Electrical Machines and Drives | Semester 2 | 1. ELECTROMECHANICAL ENERGY CONVERSION 2. TRANSFORMATIONS OF VARIABLES 3. INDUCTION MACHINES 4. SYNCHRONOUS MACHINES 5. LINEARIZATION AND REDUCED MODELS OF AC MACHINES 6. ELECTRICAL DRIVES 7. CONTROL TECHNIQUES |
| M165 | Master's Degree in Thermal Energy Systems | 51650009 | Solar Energy in Thermal Processes | Semester 1 | 1. Introduction to solar thermal energy systems 2. Solar collectors: Typology, components and characteristic parameters 3. Solar collectors: Models in permanent regime and transient regime 4. Thermal energy accumulation 5. Solar energy systems in thermal processes 6. Design methods 7. Regulations and Standards |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560021 | Structural engineering | Semester 1 | 1. Basic concepts in industrial structural design: definitions, materials, stresses, structural safety, static and dynamic behavior. 2. Basic structural types: Pin-jointed structures . 3. Matrix design of structures. Introduction to the finite element method: Application to bar structures. 4. Sizing of simple steel structures. |
| 199 | Degree in Telecommunications Technology Engineering | 1990041 | Security | Semester 2 | Block 1: Fundamentals Block 2: Network Security Block 3: Application Security Block 4: Security Management |
| 208 | Degree in Chemical Engineering | 2080049 | Heterogeneous Reactors | Semester 1 | Catalytic, gas-solid, gas-liquid, design, simulation and optimization |
| 203 | Degree in Industrial Technology Engineering | 2030095 | Functional materials | Semester 1 | Topic 0. Introduction Topic 1. Electrical properties of materials: Band model and conductors Topic 2. Electrical properties of materials: Semiconductors Topic 3. Electrical properties of materials: Insulators Topic 4. Magnetic properties of materials Topic 5. Optical properties of materials Topic 6. Thermal properties of materials Topic 7. Chemical properties of materials |
| M232 | Double MU in Aeronautical Engineering and Space Systems Operation | 52320003 | Cartography applied to drones | Semester 2 | Theoretical Content: - Topic 1: Terrestrial reference system and types of coordinates - Topic 2: Projections and cartographic products - Topic 3: Geographic Information Systems and SDI services - Topic 4: The LIDAR system and Digital Terrain Models - Topic 5: Basic principles of Photogrammetry - Topic 6: Cartographic survey - Topic 7: Precise positioning with GPS Practical Content - Practice 1: The navigator and topographic GPS. SRT changes. - Practice 2: Uses of cartographic projections - Practice 3.1: Geospatial data management - Practice 3.2: Aeronautical maps and charts - Practice 4: LiDAR - Practice 5: Flight planning - Practice 6: Cartographic survey |
| M143 | Master's Degree in Aeronautical Engineering | 51430020 | Turbomaquine design and heat transfer | Semester 1 | - Steady-state conduction. - Fins. - Transient conduction. - Radiation. Strip radiation . - Convection. Heat exchangers. - Cooled gas turbines. Gas turbine cooling solutions . - 3D flow approximation in thermal turbomachinery. - Gas turbine coupling: off-design operation. |
| 197 | Degree in Aerospace Engineering | 1970059 | Meteorology | Semester 2 | Physical phenomena in the atmosphere. Weather forecasting. Aeronautical meteorological instrumentation. Aeronautical climatology. Adverse meteorological conditions for navigation. |
| 208 | Degree in Chemical Engineering | 2080055 | Water treatment | Semester 2 | Design and analysis of purification processes. Water treatment for industrial use. Drinking water purification. |
| 197 | Degree in Aerospace Engineering | 1970053 | Air Traffic Management | Semester 1 | Airspace Regulation. Flight Procedures. Air Traffic. |
| M228 | Master's Degree in Operation of Space Systems | 52280002 | Artificial Intelligence for Space Applications and Earth Observation Missions | Semester 2 | AI Tools and Methodologies: Deep Learning, Reinforcement Learning; Linear and Quadratic Programming; Mixed Integer Programming (MIP); Heuristic Algorithms including Genetic Algorithms and Particle Swarm Optimization (PSO); Implementation of AI tools and optimization algorithms; Computational Geometry; Applications to Earth Observation missions; Space mission planning and scheduling problems. |
| 197 | Degree in Aerospace Engineering | 1970028 | Fluid Mechanics II | Semester 1 | Boundary Layer Theory and introduction to Turbulence, turbulent motion of gases in ducts, acoustics. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280045 | Electronic Instrumentation Laboratory | Semester 1 | Operating principles of sensors and actuators. Electronic instrumentation techniques. Signal conditioning principles. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900023 | Computational Techniques in Civil Engineering | Semester 1 | Part I - Fundamentals. 1 - Structured programming. 2 - Preliminary concepts of continuum mechanics. 3 - Discretization and graphical representation of results. Part II - Implementation of computational mechanics algorithms. 3 - Linear problems. 4 - Nonlinear problems, constitutive nonlinearity. 5 - Nonlinear problems, geometric nonlinearity. Part III - Structural optimization . 6 - Topological optimization. |
| 197 | Degree in Aerospace Engineering | 1970026 | Electronic Engineering | Semester 1 | Devices. Polarization. Amplification. Introduction to digital electronics. Introduction to communications. |
| M143 | Master's Degree in Aeronautical Engineering | 51430042 | Professional Practice of Engineering | Semester 2 | 1. INTRODUCTION TO ENGINEERING. APPLICATION TO THE CASE OF INDUSTRIAL ENGINEERING a. HISTORY b. PROFILE c. WORKS d. RECOGNITIONS 2. THE ENGINEERING MAP. APPLICATION TO INDUSTRIAL ENGINEERING a. SPANISH ENGINEERING FIRMS b. ENGINEERING FIRMS WORLDWIDE c. ENGINEERING ORGANIZATIONS d. PROFESSIONAL ASSOCIATIONS e. PROFESSIONAL ENGINEERING CERTIFICATIONS f. ENGINEERING DEGREES g. THE PRACTICE OF ENGINEERING AROUND THE WORLD h. INDUSTRIAL ENGINEERING STUDIES i. SOFT SKILLS FOR WORKING AS AN ENGINEER j. SUCCESS IN THE ENGINEERING PROFESSION 3. THE LEGISLATIVE FRAMEWORK OF THE ENGINEER a. COMPETENCES, ATTRIBUTIONS AND COMPETENT TECHNICIANS b. PROFESSIONAL ATTRIBUTIONS OF THE ENGINEER. ATTRIBUTIONS OF THE INDUSTRIAL ENGINEER c. PROJECT DRAFTING d. PROFESSIONAL FEES e. INDUSTRIAL LEGISLATION, RULES AND REGULATIONS f. SUBMISSION OF DOCUMENTS TO THE ADMINISTRATION g. REGULATION OF THE PROFESSION IN VARIOUS COUNTRIES h. THE CIVIL AND CRIMINAL LIABILITY OF THE ENGINEER i. JUDGMENTS FOR ATTRIBUTIONS j. JUDGMENTS FOR CIVIL LIABILITY k. PROFESSIONAL ETHICS l. COLLEGE VISA 4. FIELDS OF ACTIVITY OF THE ENGINEER. APPLICATION TO INDUSTRIAL ENGINEERING a. THE ENGINEER IN THE INDUSTRIAL COMPANY b. THE ENGINEER AS A BUSINESS DEVELOPER c. THE ENGINEER IN THE PUBLIC SERVICE d. THE ENGINEER IN THE ENGINEERING COMPANY e. THE ENGINEER IN THE SERVICE COMPANY f. THE ENGINEER IN THE MAINTENANCE COMPANY g. OCCUPATION BAROMETER FOR INDUSTRIAL ENGINEERS 5. THE INDEPENDENT PROFESSIONAL ENGINEER a. TYPES OF SELF-EMPLOYED ENGINEERS b. THE ALTERNATIVE TO THE SPECIAL REGIME FOR SELF-EMPLOYED WORKERS (RETA) 6. FROM BASIC TO DETAIL ENGINEERING a. PHASES OF INDUSTRIAL PROJECT PREPARATION b. BASIC PROJECT INFORMATION c. PERMITS AND LICENSES d. BASIC PROJECT ENGINEERING e. DETAIL ENGINEERING f. PURCHASE MANAGEMENT g. CONSTRUCTION SUPERVISION h. COMMISSIONING 7. ENGINEERING CONTRACTS a. CONTRACT TYPES b. FIDIC CONTRACTS 8. PUBLIC TENDERS a. CONCEPTS b. REQUIREMENTS c. TENDERS d. CONTRACT CONTENT e TENDER DOCUMENTS . PROPOSAL CONTENT 9. LOOKING AT THE COMPANY THROUGH AN ENGINEER'S EYES a. THE COMPANY'S ECOSYSTEM b. KNOWLEDGE ABOUT BUSINESS MANAGEMENT c. FROM MANAGER TO ENTREPRENEUR d. QUALITIES FOR SUCCESS e. WHAT TO DO AND WHAT NOT TO DO f. WHAT OTHERS HAVE ALREADY SAID |
| M190 | Master's Degree in Civil Engineering (2019) | 51900011 | Elasticity | Semester 1 | Stresses. Strain. Laws of behavior. The elastic problem. Thermal effects. Yield criteria. Principles and theorems of elasticity. Plane states. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210020 | Industrial Project Management | Semester 2 | BLOCK I: THEORETICAL FOUNDATIONS BLOCK II: PROJECT SCOPE BLOCK III: PLANNING AND SCHEDULE BLOCK IV: EARNED VALUE ANALYSIS BLOCK V: RISK PROJECT MANAGEMENT BLOCK VI: CRITICAL CHAIN BLOCK VII: MISCELLANEOUS IN PROJECT MANAGEMENT BLOCK VIII: PRACTICAL APPLICATIONS |
| M192 | Double MU in Industrial Engineering and Advanced Design in Mechanical Engineering | 51920035 | Solid Dynamics | Semester 1 | BLOCK 1. VIBRATIONS OF LINEAR SYSTEMS WITH N DOF. RANDOM VIBRATIONS OF LINEAR VIBRATORY SYSTEMS. BLOCK 2. EXPERIMENTAL MODAL ANALYSIS. VIBRATIONS IN ROTORS. BLOCK 3. DAMAGE DETECTION IN MACHINERY. |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040014 | Data Aggregation and Presentation in IoT | Semester 1 | Content in thematic blocks: Data collection. Data storage. Analysis. Data presentation. |
| 208 | Degree in Chemical Engineering | 2080043 | Computer Aided Design | Semester 1 | THEMATIC BLOCK I: GENERATION OF SOLIDS. THEMATIC BLOCK II: PRODUCTION OF DRAWINGS. THEMATIC BLOCK III: MODELING OF SHEET METAL PARTS. THEMATIC BLOCK IV: ASSEMBLY DESIGN. THEMATIC BLOCK IV: GENERATION OF LINES AND SURFACES. |
| 203 | Degree in Industrial Technology Engineering | 2030093 | Control Laboratory | Semester 1 | - Introduction to software tools for driver implementation - Identification of real systems |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280037 | Industrial Process Control | Semester 1 | Ability to design instrumentation systems for control. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210128 | Advanced Materials Mechanics | Semester 2 | PART 1: MECHANICS OF COMPOSITE MATERIALS (24H) BLOCK 1: ANISOTROPIC ELASTICITY (9h) Topic 1.1. Introduction. Topic 1.2. Formulation of the elastic problem in anisotropic materials. Topic 1.3. Basic elastic problems for a cylindrical solid. Topic 1.4. The Finite Element Method applied to anisotropic materials. Topic 1.5. Plane Elasticity and its applications. BLOCK 2: COMPOSITE MATERIALS (9h) Topic 2.1. Introduction. Topic 2.2. Mechanical behavior of a sheet. Topic 2.3. Mechanical characterization of a sheet Topic 2.4. Mechanical behavior of a laminate. Topic 2.5. Interlaminar stresses. Topic 2.6. Analysis of structural elements of composite material. BLOCK 3: FAILURE OF COMPOSITE MATERIALS (6h) Topic 3.1. Introduction. Failure mechanisms in composite materials. Topic 3.2. Failure criteria at the lamina level. Topic 3.3. Laminate failure. Degradation models. Topic 3.4. Micromechanical aspects of composite material failure. PART 2: NANOMECHANICS OF SOLIDS (16h) BLOCK 4: NANOMECHANICS OF SOLIDS (16h) Topic 4.1. Introduction to crystal lattices and their defects. Topic 4.2. Multiscale modeling of materials. Computational methods. Topic 4.3. Interatomic potentials. Topic 4.4. Energy stored in a crystal with defects. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550003 | Dynamics of Multibody Systems | Semester 2 | The course consists of two thematic blocks: - Computational Kinematics - Computational Dynamics The first block, Computational Kinematics, shows the machine modeling techniques for simulation, including the selection of coordinates and reference systems and the kinematic restrictions to which they are subject. Based on the model, the computational techniques for analyzing position, velocity and acceleration that allow kinematic simulation are shown. The second block, Computational Dynamics, shows the automatic formulation and calculation of the equations of motion of multibody systems in their ODE and DAE forms. The block continues by showing the numerical methods for solving these equations in the time domain that allow the dynamic simulation of machines. |
| 203 | Degree in Industrial Technology Engineering | 2030157 | Treatment of Gaseous Effluents | Semester 1 | Air pollutant abatement techniques. Industrial design and implementation. |
| 199 | Degree in Telecommunications Technology Engineering | 1990003 | Programming Fundamentals I | Semester 1 | Part 1: Programming Basics Part 2: Data Types and Flow Control Part 3: Functions Part 4: Memory Management Part 5: Functions and Dynamic Structures |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210046 | Machine Technology | Semester 1 | Vibrations of mechanical systems. Vibration isolation. Effects of varying stresses: fatigue. |
| M181 | Master's Degree in Chemical Engineering | 51810014 | Numerical Methods in Chemical and Environmental Engineering | Semester 1 | Introduction to MATLAB and Numerical Analysis. Systems of linear equations. Interpolation. Nonlinear optimization and equation solving. Numerical methods for ordinary and partial differential equations. |
| 199 | Degree in Telecommunications Technology Engineering | 1990024 | Digital electronic | Semester 1 | Analysis and design of combinational and sequential, synchronous and asynchronous circuits. Fundamentals of hardware description languages. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980045 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210126 | Advanced Fluid Mechanics | Semester 2 | I. Review of the Navier-Stokes equations. II. Computational fluid dynamics (CFD) III. Application of CFD to engineering flows REFERENCES A. BARRERO and M. PEREZ-SABORID, Introduction to Fluid Mechanics and its Applications, Ed. McGraw-Hill, 2005. F. M. WHITE, Fluid Mechanics, Ed. McGraw-Hill, 2004. G. K. BATCHELOR, An Introduction to Fluid Dynamics, Ed. Cambridge University Press, 1967. LANDAU and LIFSHITZ, Fluid Mechanics, Pergamon Press. SCHLICHTING, Boundary Layer Theory, Ed. McGraw-Hill. (There is a Spanish version 'Boundary Layer Theory' in the ETSI Library) |
| M143 | Master's Degree in Aeronautical Engineering | 51430001 | Aircraft calculation and aircraft systems | Semester 1 | --------------------- English Version : Preliminary aircraft sizing. Design and study of aircraft systems. Aerodynamic study of aircraft. Aircraft stability and control study. Aircraft structural study. Study of aircraft performance and propulsion. Concurrent engineering tools in aircraft design. Aircraft design optimization tools. --------------------- SPANISH: Preliminary aircraft sizing. Design and study of aircraft systems. Aerodynamic study of aircraft. Study of aircraft stability and control. Aircraft structural study. Study of aircraft performance and propulsion. Concurrent engineering tools in aircraft design. Aircraft design optimization tools. |
| M160 | Master's Degree in Electronic, Robotic and Automatic Engineering | 51600004 | Vehicle Control | Semester 2 | 1. Introduction to Automotive Control 2. Modeling for Automotive Control 3. Propulsion System Control. Electric and Hybrid Vehicle Control 4. Dynamics Control: Traction, Stability, and Braking 5. Other Controls 6. Introduction to Intelligent Transportation Systems |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270020 | Hydraulic Technology and Machines | Semester 2 | Basic principles of fluid mechanics. Dimensionless analysis. Hydraulic installations. Calculation of piping and fitting systems. Hydraulic turbomachinery. Characteristic curves. Auxiliary elements. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270016 | Automatic and processes control | Semester 2 | Modeling of dynamic systems. Analysis of linear systems. Design and implementation of basic control systems. Practical applications. |
| 199 | Degree in Telecommunications Technology Engineering | 1990059 | Electronic Systems Projects | Semester 1 | Electronic circuit and system projects |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210042 | Integrated Manufacturing Systems | Semester 1 | The course content is tailored to the following descriptors: - Technologies for manufacturing integration. - Integrated manufacturing systems. - Digital manufacturing. - Rapid prototyping. Additive manufacturing. |
| M155 | Master's Degree in Advanced Design in Mechanical Engineering | 51550010 | Advanced Fluid Mechanics | Semester 2 | I. Review of the Navier-Stokes equations. II. Computational fluid dynamics (CFD) III. Application of CFD to engineering flows REFERENCES A. BARRERO and M. PEREZ-SABORID, Introduction to Fluid Mechanics and its Applications, Ed. McGraw-Hill, 2005. F. M. WHITE, Fluid Mechanics, Ed. McGraw-Hill, 2004. G. K. BATCHELOR, An Introduction to Fluid Dynamics, Ed. Cambridge University Press, 1967. LANDAU and LIFSHITZ, Fluid Mechanics, Pergamon Press. SCHLICHTING, Boundary Layer Theory, Ed. McGraw-Hill. (There is a Spanish version 'Boundary Layer Theory' in the ETSI Library) |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980041 | Energy Management in Industry | Semester 2 | 1. Energy consumption in the industrial sector. 2. Energy audit methodology. 3. Thermal installations in industry. 4. Industrial equipment and processes. 5. Energy-saving measures. 6. Regulations |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970039 | Numerical Methods for Electrical Systems | Semester 2 | - Storage and manipulation of sparse matrices. - Solution of linear systems. - Stability and ill-conditioning. High-dimensional systems. Optimal node ordering. - Linear optimization problems . - Nonlinear optimization problems . - Mixed integer optimization problems. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940038 | Microsystems and Nanotechnologies | Semester 2 | THEMATIC BLOCKS 1. INTRODUCTION TO MICROSYSTEMS. 2. APPLICATIONS OF MICROSYSTEMS. 3. DESIGN AND MANUFACTURING A MICROSYSTEM. 4. INTRODUCTION TO NANOTECHNOLOGY. |
| M190 | Master's Degree in Civil Engineering (2019) | 51900031 | Urbanization Works | Semester 2 | Teaching will be provided through theoretical classes given by the professor, distributed in THEMATIC BLOCKS, in accordance with the contents specified by the descriptors of the Master's Thesis, which have been expanded with some contents that are considered professionally essential, for the training of excellent professionals who will qualify for the studies of Civil Engineer, Canals and Ports, once the contents of the subjects of the current teaching plan have been analyzed. BLOCK I - THE DESIGN OF URBAN ROADS, AIRPORTS AND PORTS This block will deal with the design aspects of the urbanization process of Urban Areas and transport infrastructures such as Airports and Ports; and in particular the elements of urban roads, the mobility space, the equipment of urban space, the public transport space, road pavements and other infrastructure indicated, and the remaining aspects necessary for the adequate design or its reform. BLOCK II - DIGITAL CONSTRUCTION WITH BIM TECHNOLOGY The aim is to introduce students to the subject of developing the CONSTRUCTION INFORMATION MODEL according to the UNE-EN ISO 19.650 regulations, from the conceptual designs of urban development planning road systems to the PIM and AIM models and urbanization works (road, airport and port), allowing them to learn BIM technology and tools applied to digital construction engineering. BLOCK III - PROJECT AND MANAGEMENT OF URBANIZATION WORKS The content of the project and its elements, with special reference to the specifications of the sectorial legislation, the documents and their minimum content as well as the specific technical specifications; and finally the valuation of the works, referencing the most significant work units and the formation of their unit prices, in order to specify the budgets for the works. Regarding the execution and inspection of works, the inspiring principles of project management, the start of works, production monitoring, receipt and settlement of works will be addressed. Finally, an approach to the quality control of works will be made, in its aspects of materials control, execution control, the content of the control plan and its assessment, and the quality management system; complementing it with the essential aspects of occupational health and safety. BLOCK IV - CONSERVATION AND OPERATION OF URBANIZATION WORKS The pathology of urbanization works. Conservation management techniques and systems, including pavement auscultation and reinforcement, as well as surface renewal techniques. The operating systems of urbanization works within the scope of the subject. In particular, the contents on the following will be developed in the lectures: - The technical specifications required for construction materials applied in the works covered by the scope of the subject, and their acceptance control. - the construction techniques applied in the aforementioned structures, with a study of the materials and machinery used, as well as their performance. - the procedures (activities) applied in their execution, as well as their quality control. - the introduction of innovative digital construction (Construction 4.0). - the pathologies, conservation techniques, and operating systems of this type of civil works. Collaborative practical classes will be held by students (Workshops), following the syllabus, through Practical Cases, distributed among the different thematic blocks into which the subject is structured. A field visit will also be carried out to inspect the urban development works. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210032 | Business Organization and Management | Semester 2 | 1. General Accounting 2. Investments and Financing 3. Cost Accounting |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560060 | Machine Technology | Semester 1 | Vibrations in mechanical systems. Vibration isolation. Effects of varying stresses: fatigue. Calculation and design of machine elements. |
| 225 | Degree in Civil Engineering | 2250021 | Topography | Semester 1 | Program of the theoretical classes: Block I: INTRODUCTION - Topic 1: Basic concepts of Topography - Topic 2: Theory of errors Block II: TOPOGRAPHIC INSTRUMENTS AND METHODS - Topic 3: The Total Station - Topic 4: Planimetric methods - Topic 5: The automatic level - Topic 6: Altimetric methods - Topic 7: Methods of determining coordinates Block III: GEODESY, CARTOGRAPHY AND GLOBAL POSITIONING SYSTEMS - Topic 8: Terrestrial Reference Systems - Topic 9: Cartographic projections and cartographic surveying - Topic 10: Introduction to Global Positioning Systems Block IV: TOPOGRAPHY OF WORKS - Topic 11: Methods of staking out works - Topic 12: Topographic control of works Program of the practical classes: Practice nº 1: Use of the Total Station. Simple radiation Practice No. 2: Surveying a plot. Simple radiation Practice No. 3: Introduction to civil engineering software I (Office) Practice No. 4: Surveying a plot with a link between stations. Compound radiation Practice No. 5: Resolution of itineraries (Office) Practice No. 6: Framed itinerary Practice No. 7: Introduction to GIS (Office) Practice No. 8: Cubing Practice No. 9: Geometric leveling Practice No. 10: Introduction to civil engineering software II (Office) Practice No. 11: Determination of base coordinates and calculation of heights Practice No. 12: Use and handling of a GNSS navigator system and coordinate transformation Practice No. 13: Use and handling of a topographic GNSS system Practice No. 14: Staking out a polygonal/linear work |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940039 | Optimization and Control in Energy Systems | Semester 2 | Common thermal processes. Dynamic analysis. Process controllability. Optimization and control. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210040 | Perception Systems (AR) | Semester 2 | B1. Introduction to automatic perception B2. Image processing B3. Region separation B4. Shape recognition B5. Other automatic perception techniques |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270013 | Quantitative Methods of Operational Research | Semester 1 | -- Primal and dual linear programming. -- Network and graph modeling. -- Transportation and assignment models. -- Application to modeling and problem solving in organizational engineering. |
| 228 | Degree in Electronic, Robotics and Mechatronics Engineering (UMA-US) | 2280063 | Process Control Laboratory | Semester 2 | Ability to design instrumentation systems for control. |
| 199 | Degree in Telecommunications Technology Engineering | 1990014 | Business Organization | Semester 2 | Subject descriptors: - Concept of company - Institutional and legal framework of the company - Organization and management of companies. THEMATIC BLOCKS: BLOCK 1 - FUNDAMENTALS OF THE CONCEPT OF COMPANY BLOCK 2 - ECONOMIC ANALYSIS OF THE COMPANY BLOCK 3 - COST AND MANAGEMENT ACCOUNTING BLOCK 4 - ANALYSIS OF INVESTMENTS AND FINANCING OPERATIONS |
| 197 | Degree in Aerospace Engineering | 1970022 | Aerodynamics i | Semester 1 | Irrotational motions. General equations. Two-dimensional potential motion of ideal liquids. Linearized potential theory of airfoils in incompressible conditions. Large-span wings in incompressible conditions: Prandtl's long-wing theory. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210045 | Advanced Manufacturing Technology (IMF) | Semester 2 | - Fundamentals of Forming Processes. - Manufacturing with Composite Materials. - Advanced Forming Processes. - Manufacturing Process Simulation. |
| 199 | Degree in Telecommunications Technology Engineering | 1990004 | Mathematics I | Semester 1 | Linear algebra, geometry, complex numbers. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210130 | Micro and Nano Electronics | Semester 2 | 1. Electronic simulation with CADENCE. 2. Hardware description languages for analog circuits. 3. Basic block design. 4. Electronic system design. 5. Analog circuits in aerospace applications. |
| 199 | Degree in Telecommunications Technology Engineering | 1990007 | Programming Fundamentals II | Semester 2 | Dynamic data structures. Object-oriented programming paradigm. |
| M197 | Double MU in Industrial Engineering and Electrical Power Systems | 51970038 | Electrical Network Analysis Laboratory | Semester 2 | Laboratory Block 1: Static Analysis o Static analysis of an electrical power system o Network elements model: o Input file: *.raw o Fault detection in models o Load distribution o Analysis of the state of an electrical power system o Safety analysis of an electrical power system o Short circuit analysis of an electrical power system o Network elements model: o Input file: *.seq o Short circuit analysis instructions o Analysis of output files o OPF Block 2: Dynamic Analysis o Introduction to the dynamics of electrical power systems o Synchronous machine model: AVR, PSS, power/frequency regulator o Transient stability o Frequency stability |
| 197 | Degree in Aerospace Engineering | 1970032 | Airport Construction I | Semester 2 | Fundamentals of airport and infrastructure design and construction. Location, siting, and environmental impact of airports. Field operations. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210106 | Welding (MRI) | Semester 1 | Welding process technologies, weldability, metallurgical aspects, quality control, mechanical behavior under static and fatigue stresses, and thermal and residual stresses. |
| M193 | Double MU in Industrial Engineering and Environmental Engineering | 51930032 | Biorefineries | Semester 1 | The course is divided into four main sections that cover the following topics: - Fundamentals of Biorefineries: concepts, types, and platforms - Fundamentals of biomass transformation processes - Production of biofuels, biofuels, and bioproducts - Energy, economic, and environmental analysis of biorefineries. The first section develops the fundamental concepts of biorefineries, their classification and typology, the main processes that comprise them, experiences to date in Spain and around the world, etc. Likewise, the biomass resource, logistics, and the biomass market are studied. The second section studies biomass transformation processes, including physical and chemical pretreatment processes as well as thermochemical, biochemical, and hydrothermal conversion processes. The third section describes the production processes of biofuels (biofuels and chemicals) and bioproducts. Finally, the fourth section presents a detailed analysis of the different types of biorefineries, grouped into two large "families." thermochemical and biochemical, the different platforms that define the various biorefineries currently under development (lipids, sugars, biogas, proteins, synthesis gas, etc.) as well as an analysis of the energy and environmental efficiency of biorefineries. |
| M146 | Master's Degree in Industrial Engineering | 51460049 | Application of Computational Methods to Mechanical Design | Semester 2 | The contents of the subject are structured in four blocks: A. DYNAMICS: which covers objectives 5) and 6). B. PLASTICITY: which includes objective 3). C. FRACTURE AND FATIGUE MECHANICS: which includes objectives 1), 2) and 4). D. CONTACT: which considers objective 7). |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210006 | Company | Semester 2 | Adequate understanding of the concept of business, the institutional and legal framework of business, and business organization and management. |
| M194 | Double MU in Industrial Engineering and Electronic, Robotic and Automatic Engineering | 51940050 | Work Organization and Occupational Risk Prevention | Semester 1 | PART: HUMAN RESOURCE ORGANIZATION Module 1. Study of methods. Module 2. Work measurement. Module 3. Worker rights. PART: OCCUPATIONAL RISK PREVENTION Module 1. Basic concepts of occupational health and safety. Module 2. Prevention management. Module 3. Most common organizational risks. Module 4. Accident investigation and associated costs |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210052 | Thermoeconomics (EN) | Semester 1 | Thermoeconomics and sustainability of energy systems and processes. |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560002 | Differential and Integral Calculus | TO | Functions of one variable: Functions of one variable and their graphs. Taylor's theorem and its applications. Taylor series. Calculus of primitives. First-order differential equations. Applications of the definite integral, improper integrals. Differential geometry of curves. Functions of several variables: Scalar fields and their graphs. Partial derivatives and their applications. Optimization of scalar fields. Differential geometry of surfaces. Multiple, line, and surface integrals. Integral theorems. |
| M198 | Double MU in Industrial Engineering and Thermal Energy Systems | 51980040 | Solar Energy in Thermal Processes | Semester 1 | 1. Introduction to solar thermal energy systems 2. Solar collectors: Typology, components and characteristic parameters 3. Solar collectors: Models in permanent regime and transient regime 4. Thermal energy accumulation 5. Solar energy systems in thermal processes 6. Design methods 7. Regulations and Standards |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210069 | Methodology and History of Engineering | Semester 2 | Block 1: Science, Technology, and Engineering. Block 2: Technology up to the Classical Age. Block 3: Technology in Classical Rome, the Middle Ages, and the Renaissance. Block 4: Technology in the 17th and 18th Centuries. The Modern Age and the Enlightenment. Block 5: Technology in the 19th and 20th Centuries. Modern Engineering and New Technologies. Block 6: The Engineering Method. Aspects of the Philosophy of Technology and Science. Block 7: Engineering, Profession, and Ethics. |
| 197 | Degree in Aerospace Engineering | 1970021 | Manufacturing technology | Semester 2 | I. INTRODUCTION TO MANUFACTURING II. MEASUREMENT, VERIFICATION AND QUALITY CONTROL TECHNIQUES III. METAL CASTING PROCESSES IV. PLASTIC METAL FORMING PROCESSES V. MACHINING PROCESSES VI. FORMING OF POLYMERIC AND COMPOSITE MATERIALS VII. JOINT FORMING PROCESSES VIII. MANUFACTURING SYSTEMS |
| M204 | Master's Degree in Telecommunications Engineering (Plan 2021) | 52040021 | IoT Devices and Embedded Systems | Semester 1 | A) THEORETICAL thematic blocks 1. Introduction to IoT communication protocols 2. Standards (with emphasis on 802.15.4) 3. HW for IoT node design 4. IoT Operating Systems 5. Embedded Systems and Sensors 6.- IoT applications and power management B) PRACTICES 1. IoT applications using WSN 2. Simulation of IoT nodes using WSN |
| 256 | Degree in Industrial Technology Engineering (2024) | 2560032 | Bioengineering | Semester 2 | - Basic concepts and applications in bioengineering. - Future development prospects. - Knowledge of the technological areas involved. - Medical applications. |
| 225 | Degree in Civil Engineering | 2250013 | Electrical engineering | Semester 1 | Generation, transmission, and distribution of electrical energy. Applicable regulations. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630013 | Modeling and Optimization of Management Problems | Semester 2 | Subject descriptors: - Operations research. - Artificial intelligence applied to industrial management problems. - Optimization in Project Management. Thematic blocks: BLOCK 1: Modeling management problems. BLOCK 2: Optimization of management problems and project management. BLOCK 3: Artificial intelligence applied to industrial management problems. BLOCK 4: Project development and management. Coding of models and resolution methods. |
| 208 | Degree in Chemical Engineering | 2080034 | Thermal Machines and Engines | Semester 2 | THEMATIC BLOCK I.- INTRODUCTION Lesson 1: The heat engine and the heat motor. THEMATIC BLOCK II.- HEAT ENGINES Lesson 2: Fundamental equation of turbomachines Lesson 3: Axial turbomachines Lesson 4: Radial turbomachines Lesson 5: Volumetric compressors Lesson 6: Characteristic curves of heat engines THEMATIC BLOCK III.- HEAT ENGINES Lesson 7: Steam turbines Lesson 8: Gas turbines Lesson 9: Combined steam and gas cycles Lesson 10: Reaction engines Lesson 11: Reciprocating internal combustion engines: classification, operating principles and fundamental parameters Lesson 12: Reciprocating internal combustion engines: cycles and processes Lesson 13: Emissions from heat engines Lesson 14: Characteristic curves of heat engines Lesson 15: Fields of application of heat engines: Power generation. Cogeneration. Propulsion |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210034 | Electric Power Systems | Semester 2 | High-voltage switchgear and installations, power lines, substations, insulation coordination, grounding networks, protection of high-voltage installations and lines; voltage and frequency control; electricity markets, electricity marketing, quality of supply. |
| M163 | Master's Degree in Industrial Organization and Business Management | 51630004 | Entrepreneurship | Semester 2 | BLOCK 1 Introduction. New paradigm BLOCK 2 The entrepreneurial ecosystem BLOCK 3 Lean Startup BLOCK 4 Canvas Canvas BLOCK 5 Legal Forms and Procedures BLOCK 6 Shareholders' Agreement BLOCK 7 Business Plan |
| 203 | Degree in Industrial Technology Engineering | 2030082 | Experimentation in Chemical Engineering | Semester 2 | 1. Centrifugal fan 2. Fluidized beds 3. Heat transfer 4. Fixed beds 5. Packed tower 6. Hydraulic bench 7. Operations with solids 8. Plate column 9. Filtration of liquid suspensions 10. Pressure drops in pipes and accessories 11. Sedimentation |
| M146 | Master's Degree in Industrial Engineering | 51460055 | Efficient Design in Water Desalination Facilities | Semester 2 | BLOCK I: BASIC CONCEPTS OF DESIGN, OPERATION AND MODELING OF REVERSE OSMOSIS (RO) DESALINATION SYSTEMS (4 weeks) Chapter 1. INTRODUCTION TO WATER DESALINATION. Chapter 2. INTRODUCTION TO MODELING OF REVERSE OSMOSIS DESALINATION SYSTEMS. Chapter 3. MODELING OF RO DESALINATION SYSTEMS. Chapter 4. INTRODUCTION TO THE DESIGN OF WATER DESALINATION FACILITIES. BLOCK II: MODERNIZATION OF EXISTING RO PLANTS (1 week) Chapter 5. DESIGN PROBLEMS APPLIED TO MODERNIZATION OF RO PLANTS. BLOCK III: PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY (3 weeks) Chapter 6. BASIC CONCEPTS ON THE DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 7. PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 8. COUPLING OF PHOTOVOLTAIC SYSTEMS TO PUMPING SYSTEMS. BLOCK IV: PRE-DESIGN OF WATER DESALINATION INSTALLATIONS IN INDUSTRIAL APPLICATIONS (2 weeks) Chapter 9. PRE-DESIGN OF DESALINATION INSTALLATIONS FOR HYDROGEN PRODUCTION. Chapter 10. PRE-DESIGN OF DESALINATION INSTALLATIONS INTEGRATED IN POWER PRODUCTION PLANTS. BLOCK VI: INTRODUCTION TO RESEARCH (1 week) Chapter 11. RESEARCH IN REVERSE OSMOSIS PLANTS; PROCESSES IN DEVELOPMENT. BLOCK VII: PRACTICAL DESIGN CASES (2 weeks) Chapter 12. PRACTICAL DESIGN CASES IN VARIOUS GEOGRAPHICAL LOCATIONS Chapter 13. PRACTICAL DESIGN CASES FOR VARIOUS APPLICATIONS. |
| M165 | Master's Degree in Thermal Energy Systems | 51650004 | Efficient Design in Water Desalination Facilities | Semester 2 | BLOCK I: BASIC CONCEPTS OF DESIGN, OPERATION AND MODELING OF REVERSE OSMOSIS (RO) DESALINATION SYSTEMS (4 weeks) Chapter 1. INTRODUCTION TO WATER DESALINATION. Chapter 2. INTRODUCTION TO MODELING OF REVERSE OSMOSIS DESALINATION SYSTEMS. Chapter 3. MODELING OF RO DESALINATION SYSTEMS. Chapter 4. INTRODUCTION TO THE DESIGN OF WATER DESALINATION FACILITIES. BLOCK II: MODERNIZATION OF EXISTING RO PLANTS (1 week) Chapter 5. DESIGN PROBLEMS APPLIED TO MODERNIZATION OF RO PLANTS. BLOCK III: PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY (3 weeks) Chapter 6. BASIC CONCEPTS ON THE DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 7. PRE-DESIGN OF WATER DESALINATION PLANTS USING RENEWABLE ENERGY. Chapter 8. COUPLING OF PHOTOVOLTAIC SYSTEMS TO PUMPING SYSTEMS. BLOCK IV: PRE-DESIGN OF WATER DESALINATION INSTALLATIONS IN INDUSTRIAL APPLICATIONS (2 weeks) Chapter 9. PRE-DESIGN OF DESALINATION INSTALLATIONS FOR HYDROGEN PRODUCTION. Chapter 10. PRE-DESIGN OF DESALINATION INSTALLATIONS INTEGRATED IN POWER PRODUCTION PLANTS. BLOCK VI: INTRODUCTION TO RESEARCH (1 week) Chapter 11. RESEARCH IN REVERSE OSMOSIS PLANTS; PROCESSES IN DEVELOPMENT. BLOCK VII: PRACTICAL DESIGN CASES (2 weeks) Chapter 12. PRACTICAL DESIGN CASES IN VARIOUS GEOGRAPHICAL LOCATIONS Chapter 13. PRACTICAL DESIGN CASES FOR VARIOUS APPLICATIONS. |
| M146 | Master's Degree in Industrial Engineering | 51460095 | Perception in Automatics and Robotics | Semester 2 | 1 Inspection: texture analysis 2 Detection and monitoring: motion, Kalman filter 3 Quality control: K-means, k-distance classifier, RN 4 Localization, mapping: position estimation, environment representation, map creation. |
| M221 | Master's Degree in Industrial Engineering (2024) | 52210026 | Thermal Machines and Engines | Semester 2 | In the first block, the course presents a broad overview of heat engines and thermal motors, including components, operating modes, characteristic curves, and applications for different technologies: steam turbines, gas turbines, reciprocating engines, and combined cycles. The second block addresses the design of heat exchangers, and energy savings and efficiency. Block 1: Design and Operation of Thermal Engines (16 theoretical/practical hours + 2 laboratory hours + 2 computer hours): Steam Turbine, Gas Turbine, Combined Steam and Gas Cycle, MCIA, Applications to Cogeneration and Propulsion. Block 2: Design of heat exchangers. Energy savings and efficiency. (16 type B hours + 2 type E hours + 2 type G hours). Introduction to thermal processes and installations. Fundamentals of thermal installation design. Energy savings and efficiency: regulatory framework. Pinch Technology: heat exchanger network design. Advanced heat exchanger design. |
| 208 | Degree in Chemical Engineering | 2080028 | Environmental Technologies | Semester 1 | DESCRIPTORS : Characteristics of solid waste, water discharges, and atmospheric emissions and their effects on the environment. Environmental legislation. Pollution prevention. Treatment technologies, fundamentals, and characteristics of pollutant purification processes. |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210038 | Savings and Efficiency in Electrical Installations and Machines | Semester 1 | Introduction and generalities 1. Introduction to savings and efficiency in electrical drives and installations 2. Electrical energy audit and energy and economic evaluation of energy saving and efficiency projects 3. Structure and operation of the electrical sector 4. Energy contracting and electricity tariffs Technical and economic sizing criteria for electrical installations 5. Technical and economic sizing of reactive power compensation 6. Technical and economic sizing of electrical conductors Criteria for the selection and efficient operation of electrical machines 7. Selection and efficient operation of transformers 8. Selection and efficient operation of electric motors and drives Quality of electrical supply 9. Quality of electrical power |
| 221 | Degree in Energy Engineering from the University of Seville and the University of Malaga | 2210019 | Material resistance | Semester 2 | + STRENGTH OF MATERIALS. BASIC CONCEPTS AND EQUILIBRIUM. + TENSILE AND FLEXURE. + TORSION. + CALCULATING STRESS IN THE SECTION + BUCKLING. |
| 227 | Degree in Industrial Organization Engineering from the University of Malaga and the University of Seville | 2270062 | Computer Aided Design | Semester 1 | THEMATIC BLOCK I: GENERATION OF SOLIDS. THEMATIC BLOCK II: PRODUCTION OF DRAWINGS. THEMATIC BLOCK III: MODELING OF SHEET METAL PARTS. THEMATIC BLOCK IV: ASSEMBLY DESIGN. THEMATIC BLOCK IV: GENERATION OF LINES AND SURFACES. |
| 208 | Degree in Chemical Engineering | 2080003 | Company | Semester 1 | Adequate understanding of the concept of business, the institutional and legal framework of business. Business organization and management. Business economics. |
| 197 | Degree in Aerospace Engineering | 1970057 | Flight Mechanics | Semester 1 | Aircraft Performance. Trajectories. Stability and Control. |
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