EE Laboratories
Location of the Electronic Engineering laboratories
- Building C4
- Building C5
Use of Telematics Laboratories
| C4 S102A |
Functions and Electronic Systems (FISE) Digital Design (DGD) Programmable Electronics (PROEL) Power Electronics and Control Systems (EPSC) Ultrasound Systems. Instrumentation and Applications (US) Analog Circuits (CA) Electric Power Processing (PEE) Communications Electronics (ECOMSE) Electronics for Communications Systems (ECS) Simulation and Analysis of Circuits using PSpice (PSPICE) |
| C4 S102B |
Functions and Electronic Systems (FISE) Analog Circuits (CA) Introduction to ICT Engineering (ENTIC) Foundations of Electronics (FDE) |
| C4 S102C |
Introduction to ICT Engineering (ENTIC) Foundations of Electronics (FDE) |
| C4 S102D |
Digital Design (DGD) Programmable Electronics (PROEL) Electronic System Design for Communications (ESDC) Communications Electronics (ECOMSE) Power Electronics and Control Systems (EPSC) Electronics for Communications Systems (ECS) Simulation and Analysis of Circuits using PSpice (PSPICE) Design of Digital Electronic Systems (DSED) |
| C5 S101A |
Embedded Systems (EMB) Signal Processing (TRS) Advanced Project in Electronic Systems Engineering (PAESEL ) Integrated Circuits and Radio Frequency Systems (RICS) Design of Microprocessor-Based Systems (DSBM) |
| C5 S101B |
Electronic Instrumentation and Optoelectronics (EIO) Instrumentation and Sensors (IS) Electronic Technology (TEL) Instrumentation (INSTR) Biomedical Instrumentation Design (BID) Instrumentation and Measurement Systems (ISDM) |
| C5 S101C |
Advanced Digital Systems (ADS) Adaptive Intelligent Systems (CSAS) Design of Analog and Mixed Integrated Systems (AMS) |
Description of the Laboratories
A wide range of practices in different areas are carried out in the EE laboratories. In the first practical subjects, students learn the basics and use common laboratory instruments to design, assemble, and measure simple electronic circuits. The main example used is a control system for the environmental parameters of a library, including temperature, lighting, door open detection, acoustic noise level, and people counter.
Subsequent practices cover electronic equipment, where students specify and design equipment, circuits, and electronic systems, as well as develop criteria for system design and equipment selection. There are also practices on electronic-digital systems based on microcontrollers, using development environments and studying system signals with logic analyzers. These practices aim to guide students in building complete processing systems, with an emphasis on high-performance microprocessor families and Digital Signal Processors (DSP). Additionally, students learn about sensors, their operation, properties, and design of specific interfaces and applications.
The laboratories also focus on electronic power conversion and control circuits for communications equipment. Remote control systems, particularly those based on infrared and radio frequency, are explored, including remote controls, remote control of electronic systems, and wireless data transmission.
Other practices in the field of bioengineering help students develop criteria for designing interfaces with transducers and reducing interferences. Electromagnetic compatibility practices address specific design methods and the application of relevant rules in electronic and telecommunication systems.
The labs also offer internships in automotive electronics, analyzing the electronic systems integrated into modern vehicles. Companies like LEAR CORPORATION, KNOSOS, SEAT, COHEMAC, and FICOSA provide theoretical content and guidance. Finally , photovoltaic engineering is covered, focusing on design and implementation aspects through the description and specification of photovoltaic, electronic, and storage subsystems.
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