Bachelor's degree

Language tutorial courses aimed at training the five language skills;

Listening comprehension & speaking

Reading comprehension & writing

Oral interaction

Continuous speaking - presentations

See the full page

electromechanical energy conversions. It provides the prerequisites for further study in the EEA Master's program.

This teaching unit will:

• Enable the definition of the three-phase sinusoidal regime for balanced, unbalanced, and non-linear loads.
• Define the properties of dielectric components.
• Provide basic laws and methods for studying magnetic components.
• Define the principles, models, and experimental tests for characterizing inductors and transformers.
• Define an electromechanical system for motorization.
• Present the topologies of electric actuators and their equivalent models using a circuit-based approach. It will also provide the main characterization tests for actuator modeling.

The practical part includes an initial tutorial section followed by a practical section on the same topic, which enables students to understand and apply theoretical principles and implement measurement methods and techniques.

See the full page

Signal processing has become an essential science today: all measurement and information processing applications use signal processing techniques to extract the desired information. This course is designed to develop theoretical and practical concepts of signal processing at the bachelor's degree level. It reinforces and follows on from the "Signal Analysis" course at the associate degree level.

See the full page

The objective of this course unit is to enable students to acquire the fundamental concepts of analog electronics.

The first part is dedicated to linear analog electronics used for conditioning and processing information, particularly from sensors.

The second part focuses more specifically on the internal structure of the operational amplifiers used in the first part, with a study of the internal architecture of amplifier circuits based on bipolar transistors.

See the full page

Grafcet section (4.5 hours of lectures, 6 hours of tutorials, 6 hours of practicals)

• Definition of the standard, stages, actions, transitions, receptivity
• Classic structures, semaphore, communication
• Inputs and outputs, time
• Implementation: evolution rules and algorithms, equivalent logic equations, state machines, industrial programmable logic controllers

Logic section (3 hours of lectures, 3 hours of tutorials, 3 hours of practicals) 

• Reminders of Logic
• Coding an FSM

Architecture section (9 hours of lectures, 6 hours of tutorials, 6 hours of practicals) 

• Principles of operation of Von Neumann machines
• Addressing modes and memory access
• Wired and microprogrammed sequencers
• Principle of interrupt systems
• Inputs/outputs

Programming section (6 hours of lectures, 15 hours of practical work) 

• Implementation of peripheral programming
• C and Assembly Languages
• STM32 board

See the full page

The objective of this course unit is to enable students to acquire fundamental knowledge of embedded systems electronics, with a particular focus on digital signal acquisition and processing.

See the full page

This teaching unit is devoted to the study of continuous and discrete linear time-invariant systems. This study will be conducted solely on single-variable systems with a single input and a single output. Students will learn to analyze these systems and synthesize continuous and discrete control laws to precisely control the output variable. These lectures are accompanied by tutorials to deepen and master the concepts covered in the course. Practical work is also included in this teaching unit in order to put the concepts of the course into practice, to realize the difference between theory and practice, and ultimately to improve the student's technical skills. 

See the full page

The EEA project is carried out during semester 6 of the EEA Bachelor's degree. The topic is chosen by the student, and a teacher provides regular supervision of the project.

This project involves writing a thesis and giving an oral presentation.

See the full page

Photonics is a specialty that focuses on light, in both its wave and particle forms. Photonic solutions are essential in countless fields, such as high-speed telecommunications, medicine, aeronautics, lighting, the environment (observation, treatment), defense (night vision, guidance), metrology, etc. As part of the EEA bachelor's degree and this module, which is both practical (laboratory work) and theoretical (lectures/tutorials), the basics of electromagnetism will be covered, such as the equation for the propagation of an electromagnetic wave, the properties of these waves, and their behavior at interfaces. This will lead to the study of key phenomena in wave photonics in particular, such as diffraction and interference, which will provide an understanding of how to use light for spectroscopy analysis, to measure deformations, to encode information for very high-speed communications, to store information, etc.

See the full page

Introduction to solid-state physics and semiconductor materials, providing an understanding of the physical mechanisms at work in electronic components. The course will focus in particular on the concepts used to explain the electrical characteristics of a PN junction.

See the full page

This teaching unit lays the foundations for studying electronic power converter systems used to power electronic systems or control electromechanical actuators (motors). These devices are based on the principle of switching to achieve a theoretical efficiency of 100%. Switching requires non-dissipative power filtering (inductors and capacitors), the dimensioning of which is an important step.

This teaching unit also provides basic skills in calculating and dimensioning the thermal cooling of power semiconductor electrical devices.

It is a prerequisite for continuing on to the EEA Master's program.

See the full page