215.- TECHNICAL INDUSTRIAL ENGINEER,
INDUSTRIAL ELECTRONICS
FIRST YEAR
Physics I
Fundamentals of Computer Science
Mathematics I
Circuits Theory
Basic Electronics
Graphical Expression and C.A.D.
Digital Electronics
Physics II
Mathematics II
Electric and Magnetic Circuits
SECOND YEAR
Analog Electronic
Statistical Methods in Engineering
Automatic Regulation I
Electronic Technology I
Electric Machines
Mathematical Methods in Electronic Engineering I
Microprocessors
Power Electronic I
Electronic Instrumentation I
Automatic Regulation II
Mechanic Systems
Electronic Technology II
THIRD YEAR
Industrial Automation I
Business Administration and Production Organisation I
Industrial Information Technology I
Electronic Instrumentation II
Technical Office
Power Electronic II
Industrial Automation II
Industrial Information Technology II
Final Project
OPTIONAL COURSES
Evolution of the Scientific and Technologic Knowledge
Mathematics Laboratory
Materials in Electronic Engineering
Electronic Chemistry
Fundamentals of Hydraulic and Thermic Engineering
Drawing in Electronic Engineer
Reliability and Quality
Mathematical Methods in Electronic Engineering II
Data Transmission
Electric Instruments
Integrated Analog Circuits
Numeric Control and Control of Engines
Electromagnetic Compatibility
III-1
Business Administration and Production Organisation II
Practices
Communication Systems
Health, Safety and Ergonomics
Electric Installations
Design of Industrial Applications
Control in Power Electronic
Microelectronic
Advanced Digital Systems
Computer Based Electronic Design
Digital Control
Robotics
Industrial Inspection Systems
FIRST YEAR
16170- Physics I
Semester 1; 55 Hours
Kinetic of particles. Dynamic of particles. Scalar and vector fields. Electric field. Electric potential. Conductors and
capacitors. Electric properties of material. Magnetic field. Electromagnetic induction. Magnetic properties of
material.
Teaching Method: Lectures. Practical Problems. Laboratory Practices
Assessment: Written exam. Assessment of Laboratory Practices
16171- Fundamentals of Computer Science
Semester 1; 60 Hours
Introduction to Computer Science. Introduction to UNIX. Information Codes. Programs and Algorithms: Data and
Expressions, Structures of Control, Subprograms, Arrays, Files. Programming in C. Computer Architecture.
Peripherals.
Teaching Method: Lectures. Practical problems . Laboratory practices.
Assessment: Written exam. Assessment of laboratory practices
16172 - Mathematics I
Semester 1; 75 Hours
Introduction to lineal algebra. Linear transformations. Diagonalization. Quadratic forms. Introduction to
infinitesimal calculus. Differentiation of functions in one variable. Integral of functions in one variable.
Teaching Method: Lectures. Practical problems. Lectures in the computer room.
Assessment: Written exam. Practical trial using computers. Assessment of practical works.
16173- Circuits Theory
Semester 1; 60 Hours
Basic elements and laws. Analysis and theorems. Analysis and synthesis of electrical networks: permanent and
transients.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of laboratory practical.
16174- Basic Electronics
Semester 1; 60 Hours
Semiconductors. Diodes. Bipolar transistors. Polarisation stability of the bipolar transistor. Unipolar transistor.
Polarisation stability of the unipolar transistor. Basics of amplifiers. Single stage amplifiers.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16175- Graphical Expression and C.A.D.
Semester 2; 75 Hours
III-2
Representation techniques. Fundamental standardisation in Technical Drawing. Introduction to CAD. Industrial
standardisation. Fundamentals of industrial design in the specialism.
Teaching Method: Lectures. Individual practical exercises. Computer aided design.
Assessment: Written exam. Assessment of the practical exercises.
16176- Digital Electronics
Semester 2; 75 Hours
Combinational part: Introduction to digital logic. Logic functions, minimisation. Types of logic circuits: TTL
CMOS, others... Binary codes. Combinational MSI circuits. Arithmetic and logic operations. Sequential part: Flipflops. Sequential circuits. Counters and shift registers. Memories.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16177- Physics II
Semester 2; 60 Hours
Wave movements. Mechanic Waves. Electromagnetic Waves. Composition of wave movements. Reflection and
Refraction of waves. Stationary Waves. Study of the Principles of Thermodynamics.
Teaching Method: Lectures. Practical problems. Laboratory practical
Assessment: Written exam. Assessment of the laboratory practical
16178 - Mathematics II
Semester 2; 75 Hours
Numeric Methods. Calculus in more than one variable. Introduction to differential equations
Teaching Method: Lectures. Practical problems. Lectures in the computer room.
Assessment: Written exam. Practical trial using computers. Assessment of practical works.
16179- Electric and Magnetic Circuits
Semester 2; 45 Hours
Techniques for analysis and fundamental theorems. Tree-phase systems. Magnetic circuit. Circuits with magnetic
coupling. Resonant circuits.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Assessment of the laboratory practical.
SECOND YEAR
16185- Analog Electronic
Semester 1; 60 Hours
Multi-stage amplifiers, Power amplifiers, Frequency response in amplifiers, Differential Amplifier, Structure and
Features of operational amplifier, Linear applications of operational amplifier, No linear applications of operational
amplifier.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practical is required.
16186- Statistical Methods in Engineering
Semester 1; 60 Hours
Data description, Uni-dimensional distributions. Multi-dimensional variables distributions. Probability and its
properties. Random variables. Distribution models. Introduction to statistical inference. Punctual estimation. Interval
estimation. Parametric hypothesis test. Non parametric tests.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Practical problems assessment
16187- Automatic Regulation I
Semester 1; 45 Hours
Introduction to control systems. Theory of systems. Laplace and Z transformation. External description of
dynamical systems SISO. Sampled data systems. Temporal response in continuous and discrete systems.
Teaching Method: Lectures. Laboratory practical. Practical problems.
Assessment: Written exam. Laboratory practical assessment. Laboratory trial.
III-3
16188- Electronic Technology I
Semester 1; 45 Hours
Manufacturing and design techniques. Conductors. Resistors. Capacitors. Magnetic material. Coils and transformers.
Teaching Method: Lectures. Laboratory practical. Practical problems.
Assessment: Written exam. Laboratory practical assessment..
16189- Electric Machines
Semester 1; 60 Hours
Transformers. Induction AC machines. CC Machines. Synchronous AC Machines.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16190- Mathematical Methods in Electronic Engineering I
Semester 1; 60 Hours
Further differential equations. Numerical resolution of differential equations. Series. Fourier Series.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16191- Microprocessors
Semester 1; 60 Hours
The microprocessor. Input and Output. The MC68000. Hardware interface in MC68000. Interruptions in MC68000.
Teaching Method: Lectures. Laboratory practical. Practical problems.
Assessment: Written exam. Laboratory practical assessment. Laboratory trial.
16192- Power Electronic I
Semester 2; 60 Hours
Introduction, The Power Diode, The Power Tiristor, Losses of power in semiconductors. The set semiconductorradiator. Introduction to CA/CC transformers. Phase Control in no real CA/CA transformers.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practical is required
16193- Electronic Instrumentation I
Semester 2; 45 Hours
Analog operators modules. Basic circuits for measurement. Voltage and intensity reference. Signal conditioner for
resistance transducers. Instrumentation amplifiers and isolation.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16194- Automatic Regulation II
Semester 2; 50 Hours
Frequency response in SISO continuos and discrete systems. Stability and precision in SISO continuos and discrete
systems. Series continuos and discrete controller. Root outlines. Design of continuos and discrete controller.
Teaching Method: Lectures. Laboratory practical. Practical problems.
Assessment: Written exam. Laboratory practical assessment. Laboratory trial.
16195- Mechanic Systems
Semester 2; 60 Hours
Cinematic chains. Movement of engines. Analysis of speed. Analysis of acceleration. Inertia. Gears. Flexible joins.
Screws.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16196- Electronic Technology II
Semester 2; 45 Hours
Manufacturing of techniques integrated circuits.
Teaching Method: Lectures. Laboratory practical. Practical problems.
Assessment: Written exam. Laboratory practical assessment..
III-4
THIRD YEAR
16204- Industrial Automation I
Semester 1; 45 Hours
Introduction to industrial logic automatism and synthesis of automatism.
Teaching Method: Lectures.
Assessment: Written exam.
16205- Business Administration and Production Organisation I
Semester 1; 60 Hours
The enterprise and the market. Business decisions. Management Support.
Teaching Method: Lectures.
Assessment: Written exam. Continuos work.
16206- Industrial Informatics
Semester 1; 60 Hours
Computer networks.
Teaching Method: Lectures.
Assessment: Written exam.
16207- Electronic Instrumentation II
Semester 1; 45 Hours
Linear response in transducers. Interference. Introduction to transducers. Mechanic transducers. Temperature
transducers.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Practical work.
16208- Technical Office
Semester 1; 60 Hours
Functions developed in the technical manufacturing office. Procedures for organising the production department.
Introduction to carrying out technical studies. Project management.
Teaching Method: Lectures.
Assessment: Written exam. Practical work.
16209- Power Electronic II
Semester 2; 60 Hours
Power converters CA/CC, CC/CA, CA/CA and CC/CC.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practical is required.
16210- Industrial Automation II
Semester 2; 45 Hours
Structure of programmable logic controllers
Teaching Method: Lectures.
Assessment: Written exam.
16211- Industrial Informatics II
Semester 2; 45 Hours
Further UNIX and connectivity in UNIX.
Teaching Method: Lectures.
Assessment: Written exam.
16212- Final Project
Once all the obligatory courses have been collected, a Final Project has to be worked out. It also has to be defended
by the author in front of a committee of Professors appointed by the School-Board. Both requirements need to be
successfully me before receiving the official Diploma (Bachelor Degree).
III-5
OPTIONAL COURSES
16180- Evolution of the Scientific and Technologic Knowledge
Semester 2; 30 Hours
Historic evolution of the technique. Historic evolution of the science.
Teaching Method: Lectures.
Assessment: Written exam.
16181- Mathematics Laboratory
Semester 1; 30 Hours
Solving numeric algorithms using computers.
Teaching Method: Laboratory practices
Assessment: Laboratory trial with computer or continuous work.
16182- Materials in Electronic Engineering
Semester 2; 30 Hours
Essential knowledge about the materials used in electronic
Teaching Method: Lectures
Assessment: Oral exam.
16183- Electronic Chemistry
Semester 2; 30 Hours
Electronic properties of solids. Electro-chemistry
Teaching Method: Lectures
Assessment: Oral exam
16184- Fundamentals of Hydraulic and Thermic Engineering
Semester 2; 30 Hours
Fundamental knowledge about fluid mechanics and thermic engines and compressors.
Teaching Method: Lectures. Practical problems. Laboratory practices
Assessment: Written exam.
16197- Drawing in Electronic Engineer
Semester 2; 45 Hours
Standard symbols used in electronic. Standards for drawing schemes and diagrams. Software for designing
electronic diagrams.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of practices
16198- Reliability and Quality
Semester 2; 45 Hours
Reliability. Easy of maintenance. Availability. Quality controls. Measurement. Manufacturing processes.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of practices
16199- Mathematical Methods in Electronic Engineering II
Semester 2; 45 Hours
Numerical resolution of differential equations. Fourier Series.
Teaching Method: Laboratory practical.
Assessment: Laboratory trial with computer or continuous work.
16200- Data Transmission
Semester 2; 45 Hours
Data communication: basic concepts. Networks and services. OSI. LAN networks. Ethernet. WAN networks.
Teaching Method: Lectures
Assessment: Oral exam
III-6
16201- Electric Instruments
Semester 2; 60 Hours
Protection devices, Operation devices, Electromagnetic contactor. Motor drives. Power electronic converters.
Teaching Method: Lectures. Practical problems. Laboratory practical. Simulation Software
Assessment: Written exam.
16202- Integrated Analog Circuits
Semester 2; 60 Hours
Practical study of the operational amplifier. Sinusoidal Oscillator. Active filters. Integrated subsystems with bipolar
technology. Linear sources. Noise.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam.
16203- Numeric Control and Control of Engines
Semester 2; 60 Hours
Further knowledge about electric engines control and machines control.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of practices
16213- Electromagnetic Compatibility
Semester 2; 45 Hours
Definitions. Standards. Sources and coupling.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of practices in work groups.
16214- Business Administration and Production Organisation II
Semester 2; 45 Hours
The economic activity...
Teaching Method: Lectures.
Assessment: Written exam. Continuos work.
16215- Practices
Semester 2; 45 Hours
The student should look for an enterprise where he will stay doing a technical activity.
Teaching Method: The student will have an engineer responsible in the company and a professor in the School.
They should advise to the student in their work.
Assessment: The responsible professor should assign a mark to the student from a final report.
16216- Communication Systems
Semester 2; 45 Hours
The electromagnetic spectrum. Db and noise. Modulations. Transmission lines. Digital systems. Optical
communications. Modern telecommunication systems.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practice
16217- Health, Safety and Ergonomics
Semester 2; 45 Hours
Risks. Safety. Fire. Health. Pollution. Ergonomic. Legislation.
Teaching Method: Lectures.
Assessment: Written exam. Practical work
16218- Electric Installations
Semester 1; 60 Hours
High voltage installations. Industrial electric installations. Electric installations in public services. Electric
installations in housing. Public and industrial illumination. Modern installations: buses. Software. Special
installations. Protection in low voltage. installations
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Assessment of practices
III-7
16219- Design of Industrial Applications
Semester 2; 60 Hours
Deep study of methods for designing power converters and types of protections to use, depending on the type of
charges.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practical is required.
16220- Control in Power Electronic
Semester 2; 45 Hours
CA/CC converters modelling. Design of regulation systems. Modelling and control of CC/CC converters.
Teaching Method: Lectures. Practical problems. Laboratory practice
Assessment: Written exam. Assessment of practices
16221- Microelectronic
Semester 1; 60 Hours
MOS transistor. Logic families. Featuring of circuits. Full-custom design. Alternative logic structures. Synchronism.
Input/output.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Assessment of practices
16222- Advanced Digital Systems
Semester 2; 60 Hours
Input/output devices. The 68000 in complex systems. Buses.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Practical work.
16223- Computer Based Electronic Design
Semester 2; 45 Hours
Methodologies for designing electronic circuits by using software tools: MicroSim.
Teaching Method: Lectures. Laboratory practical.
Assessment: Laboratory trial or practical work
16224- Digital Control
Semester 1; 60 Hours
General overview of advanced control, implemented in computers.
Teaching Method: Lectures. Practical problems.
Assessment: Written exam. Assessment of practices.
16225- Robotics
Semester 2; 60 Hours
Kinematics, Dynamics, Planning of paths, Programming of the Robot, Detection, Programming Language.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Assessment of practices
16226- Industrial Inspection Systems
Semester 2; 45 Hours
Sensors, Processing techniques, pattern recognition, automatic visual inspection.
Teaching Method: Lectures. Practical problems. Laboratory practical.
Assessment: Written exam. Laboratory practice
III-8