ECAM ENGINEERING PROGRAM
Combined Bachelor's / Master's Degree
SEMESTER 7
TEACHING UNIT ECTS TEACHING UNIT COMPONENT Content TEACHING HOURS
Energy Engineering courses S7 12 Advanced Electrical Machines & Applications

This course covers the basics needed for the design of an electrical machine. It introduces the different electrical machines, their components, and the main definitions / technical vocabulary needed for the design. It also sheds the light on the different methods of numerical modelling of magneto static systems as well as the finite element approach for the synchronous machine modelling. This course presents the basic analytical method for designing the various parts of a machine while relying on the client requirements (operating voltage, needed speed, geometrical sizing…). It also provides the student with the in depth knowledge needed to simulate the machine's construction using CAD and Matlab software.

Lectures : 4h00
Tutorials : 2h00
Lab Work : 12h00
Compressible Flows & Propulsion Systems

• Jet propulsion systems and their performance criteria applied to Air-Breathing and Rocket engines: Thrust; Specific Impulse; Propulsion efficiency; Tsiolkovsky rocket equation; Breguet aircraft equation.
• Fundamental of Compressible flows: Mach number and thermodynamics of compressible flows; Shockwaves; Conservation laws; application to Isentropic flows.
• Rocket engine design: Stagnation and critical states; operating mode of nozzles in rocket engines; influence of combustion pressure and temperature and of nozzle geometry on the thrust finally produced. Calculation of the resulting specific impulse.
• Propulsion systems combustion processes: influence of fuel composition and of Air-Fuel Ratio on the performance of air-breathing combustion processes; use of liquid and solid propellants in rocket engine combustion processes.
• Air-breathing propulsion turbomachines: Thermodynamic cycles used in turbojet or turbofans engines; influence of pressure ratios, air and fuel mass flow rates, blades geometries on the engine performances (specific impulse, propulsion efficiency and specific fuel consumption).

Lectures : 12h00
Tutorials : 24h00
Computational Fluid Dynamics

This course introduces the student to the subject of Computational Fluid Dynamics, as well as numerical methods for predicting fluid flows and heat transfer in flows. This course aims to help students get a good level of expertise in flow modeling for engineering applications by conducting practical work on a well-known commercial tool.
Lectures content (6h)
• Introduction to CFD: CFD fundamentals, principles, and steps
• Turbulence modeling for CFD part I: Turbulence characteristics and properties, Mean-flow equations
• Turbulence modeling for CFD part II: Turbulent-viscosity models (RANS models), Near-wall treatments
Practical work: (16h)
• Introduction to Ansys Fluent CFD tool: Fluid Flow and Heat Transfer in a Mixing Elbow
• Practice on Ansys Fluent CFD tool: Modeling external Compressible Flow
• Practice on Ansys Fluent CFD tool: Modeling Transient Compressible Flow
• Practice on Ansys Fluent CFD tool: Assessment project

Lectures : 6h00
Lab Work : 16h00
Control Theory 2a (Digital Control Systems)

1. Introduction to signals : continuous/ sampled/ discrete
2. Distinction between Difference equation (used to describe Discrete systems) and differential equation (used to describe continuous systems)
3. Signal sampling and quantization
*Sampling of continuous signals
*Signal reconstruction
*Practical considerations for signal sampling : anti-aliasing filter
*Practical reconsiderations for signal reconstruction :anti-image filter and equalizer
*Analog to digital conversion
*digital to analog conversion/quantization
4. Determination of the z-transform
*Introduction to the z-transform and its properties
*Illustration of how we determine the inverse of z-transform using the partial fraction expansion
*The use of the z-transform to solve linear difference equations
5. Digital Proportional, PI and PID controllers
*Determination of the equation of the digital controller (case of P , PI and PID)
*The implementation of digital P, PI and PID on real systems and the evaluation of the system performances

Lectures : 6h00
Tutorials : 6h00
Lab Work : 8h00
Gas Turbines

• Gas turbine technologies (Heavy Duty, aeroderivatives, etc.), improvements (cogeneration, combined cycles) and uses.
• Gas turbines specific combustion processes: operating modes, thermodynamics models, practical fuels and pollutants management.
• Theory of turbomachines applied to compressible flows and gas turbines.
• Gas turbines thermodynamic cycles.
• Main components and technological aspects of gas turbine technologies.

Lectures : 10h00
Industrial and Supply Chain Management courses S7 12 Manufacturing Digital Transformation

• Information Systems & ERPs (Enterprise Ressource Planning) in Supply Chain, Information Systems Project Management, Enterprise Resources Planning - ERP :
- Strong theoretical knowledge about IS & ERP and the link with project management
+ Application on an actual ERP, using the connected speaker
• Robotization Methodology :
- Initiation to a method of implementation of robotic equipment
- To determine the cost effectiveness of robotization on workstation
- Difference robot/cobot (strategic, productivity, safety ...)
- Risk analysis
- Robotisation criteria
• Product Lifecycle Management - PLM :
- PLM Introduction
- Windchill PLM software
- Project view
• Total Productive Maintenance 2 - TPM :
- Reliability functions, probability density functions. Serie and Parallele systems Failure rate, MTTF (Mean Time To Failure), MTBF (Mean Time Between Failure), MTTR (Mean Time To Repair)
• Plant Layout 2 :
- Redo the implementation from last year, with the simulation flows of a robotic equipment

Lectures : 8h00
Tutorials : 20h00
Project : 22h00
Global, External and Circular Supply Chain

- Information Systems in Supply Chain
- Focus on ERP
- Demand Management
- Forecasting Management
- Warehouse and Distribution Management
- Procurement strategies and Suppliers Management
- The Blue Connection: serious game in a web-based simulation environment about Circular Economy

Lectures : 8h00
Tutorials : 20h00
Project : 22h00
Innovation project S7 8 Innovation Project

The core contents are all related to the developed skills aforementioned and follow the structure of the project.

Lectures : 38h00
Tutorials : 66h00
Project : 96h00
Mechanical Design Engineering courses S7 12 Advanced Vibrations

The presentation of the relations between the physical properties of a mechanical system and its vibratory behavior is carried out in the form of lectures on the following points:

1 - Vibration of a system with one degree of freedom:
Conservative System: Free Movement - Clean Pulsation - Kinetic Energy and Deformation Energy.
Non-conservative system: Viscous damping model - Frequency response - Resonance.

2 - Vibrations of discrete systems with n degrees of freedom:
Modes of vibration - Calculation of modal characteristics - Decoupling of equations of motion - Proportional damping model - Modal superposition - Frequency response - Experimental modal analysis.

3 - Vibration reduction methodology:
Vibration isolation - Modification of a natural frequency - Increase of the damping - Use of a dynamic dampener granted

Lectures : 16h00
Lab Work : 8h00
Compressible Flows & Propulsion Systems (Mechanical Pathway)

• Jet propulsion systems and their performance criteria applied to Air-Breathing and Rocket engines: Thrust; Specific Impulse; Propulsion efficiency; Tsiolkovsky rocket equation; Breguet aircraft equation.
• Fundamental of Compressible flows: Mach number and thermodynamics of compressible flows; Shockwaves; Conservation laws; application to Isentropic flows.
• Rocket engine design: Stagnation and critical states; operating mode of nozzles in rocket engines; influence of combustion pressure and temperature and of nozzle geometry on the thrust finally produced. Calculation of the resulting specific impulse.
• Propulsion systems combustion processes: influence of fuel composition and of Air-Fuel Ratio on the performance of air-breathing combustion processes; use of liquid and solid propellants in rocket engine combustion processes.
• Air-breathing propulsion turbomachines: Thermodynamic cycles used in turbojet or turbofans engines; influence of pressure ratios, air and fuel mass flow rates, blades geometries on the engine performances (specific impulse, propulsion efficiency and specific fuel consumption).

Lectures : 12h00
Tutorials : 24h00
Computational Fluid Dynamics

This course introduces the student to the subject of Computational Fluid Dynamics, as well as numerical methods for predicting fluid flows and heat transfer in flows. This course aims to help students get a good level of expertise in flow modeling for engineering applications by conducting practical work on a well-known commercial tool.
Lectures content (6h)
• Introduction to CFD: CFD fundamentals, principles, and steps
• Turbulence modeling for CFD part I: Turbulence characteristics and properties, Mean-flow equations
• Turbulence modeling for CFD part II: Turbulent-viscosity models (RANS models), Near-wall treatments
Practical work: (16h)
• Introduction to Ansys Fluent CFD tool: Fluid Flow and Heat Transfer in a Mixing Elbow
• Practice on Ansys Fluent CFD tool: Modeling external Compressible Flow
• Practice on Ansys Fluent CFD tool: Modeling Transient Compressible Flow
• Practice on Ansys Fluent CFD tool: Assessment project

Lectures : 6h00
Lab Work : 16h00
Materials 4 (Polymers)

Macromolecules: degree of polymerization, tacticity, synthesis.
Polymers: structures, thermoplastics, thermosets, state changes, thermal and mechanical properties, additives.
Specific applications of polymers. The use of conductive polymers, bio-sourced and biodegradable polymers, polymers for packaging or fuel cells are discussed. The interest of developing copolymers is also treated.

Lectures : 10h00
Tutorials : 10h00
Lab Work : 8h00
Professional and Personal Development S7 3 Business and Sales

Students will be asked to draw on the concepts learned in previous classes such as Communication, Management, and Principles of Marketing in order master various sales techniques.

Tutorials : 12h00
Entrepreneurship 2

The course will immerse students into the key themes and debates in entrepreneurship. The focus will be on the most common questions asked by entrepreneurs willing to start a company from scratch.
The practical aspects of building a startup will be discussed. The main takeaways from the best and the worst practices will be seen.

The course addresses mainly students who are interested in/curious about creating a start-up. It does not require any specific prerequisites for the 2022-2023 academic year.

The following questions will shape the content of the course:
What is the motivation behind building a start-up?
Should you start a company?
How to go from an idea to a high-tech product?
How to make a product that users want?
How to talk to customers?
When should you launch?
All about pivoting: strategy and growth
When, why, and how is fundraising?

Tutorials : 12h00
International Relations & Natural Resources

The academic discipline of International Relations traditionally focuses on political relationships between sovereign nation-states and non-state actors in the modern world. This module aims to understand our contemporary international system using three frameworks: realism, liberalism and identity theory. We pay special attention to the role of natural resources in conflict as these resources are directly related to many fields of engineering. There will also be a historical analysis, because you cannot understand our contemporary system, without understanding the events that have shaped it!

Lectures : 6h00
Tutorials : 6h00
Robotics & IT Courses S7 12 Advanced Robotics

-Numerical Jacobian, singularity avoidance
-Trajectory and path planning for robot arms
-Performance evaluation : accuracy, precision, load, repeatability, workspace
-Dynamics of a robot arm (inertia, Coriolis)
-Visual servoing
-Programming a robotic arm and a mobile robot

Lectures : 12h00
Tutorials : 12h00
Lab Work : 12h00
Control Theory 2a (Digital Control Systems)

1. Introduction to signals : continuous/ sampled/ discrete
2. Distinction between Difference equation (used to describe Discrete systems) and differential equation (used to describe continuous systems)
3. Signal sampling and quantization
*Sampling of continuous signals
*Signal reconstruction
*Practical considerations for signal sampling : anti-aliasing filter
*Practical reconsiderations for signal reconstruction :anti-image filter and equalizer
*Analog to digital conversion
*digital to analog conversion/quantization
4. Determination of the z-transform
*Introduction to the z-transform and its properties
*Illustration of how we determine the inverse of z-transform using the partial fraction expansion
*The use of the z-transform to solve linear difference equations
5. Digital Proportional, PI and PID controllers
*Determination of the equation of the digital controller (case of P , PI and PID)
*The implementation of digital P, PI and PID on real systems and the evaluation of the system performances

Lectures : 6h00
Tutorials : 6h00
Lab Work : 8h00
Control Theory 2b (Multivariable Control Systems)

1. System representation : the state-space representation SSR of monovariable and multivariable systems
2. Determinantion of the system's Block diagram
3. Determinantion of the State space representations in canonical forms : Controllable,Observable,Diagonal/Jordan
4. Evaluation of the Controllability and the observability of a given LTI system using the Kalman citerion
5. Design of State-feedback controller using the Ackermann's formula
6. Analysis of system performances : precision, rapidity, robustness against the presence of disturbances
7. System linearization using the Tylor expansion

Lectures : 6h00
Tutorials : 6h00
Lab Work : 8h00
IT & Robotic Labs

The scrum methodology is introduced to the students. Then, they apply this agile framework during the whole duration of the project.
Each group of students receives a project of robotic application. They state the problem before designing the robotic system that corresponds to the specifications. Then, they build their system and test it extensively.
Finally, each group presents their work and write a report describing the technical and managerial aspects of the project.

Lab Work : 28h00
Students Life Commitment 3 Students Life Commitment Sem 7

Students Life Involvement 2 Students Life Involvement Sem 7

Sustainable Management S7 4 Carbon Footprint

This course is an introduction to the carbon footprint calculation method proposed by a French association, "Association Bilan Carbone".
It will consist of a :
- Reminders about Green House Gases and introduction to global warming potential
- Definition of carbon footprint
- Definition of the 3 scopes
- Presentation of the carbon Footprint computation method
- Presentation of th Carbon Footprint approach

Lectures : 4h00
Tutorials : 5h00
Corporate Social Responsibility

This course is an introduction to the CSR, it will consist of :
- An introduction to the CSR
- An explanation of how to build a CSR strategy

Lectures : 4h00
Tutorials : 10h00
Operational Quality and Lean Management

Introduction to experience plans :
- What is an experience plan and how to implement it ?
- Several notions : factors, levels of the factors, mathematical model
- Experience plans : 2 factors and 2 levels
- Experience plans : 3 factors and 2 levels

Product FMECA :
One case of study to understand what is the purpose of product FMECA and how to implement it : how to reduce the problem at the conception phase of a product

Lean-6 sigma tools :
Discovery of the different lean tools in the context of a problem-solving approach :
- What is the Lean (context and historical approach)
- What is 6 sigma (context and historical approach)
- What are the tools related to these topics (DMAIC, 5S, Ishikawa, root causes : 5W…)
- Possiblity to implement all of these tools with one tutorial : A3 problem solving method.

Lectures : 4h00
Tutorials : 12h00
SEMESTER 7 30 Pied de interne 3 Pied de interne 4 Pied de interne 5
SEMESTER 8
TEACHING UNIT ECTS TEACHING UNIT COMPONENT Content TEACHING HOURS
Energy Engineering courses S8 12 Energy Project

Group Project structured around various sessions of group work with access to the necessary computer resources.

Project : 36h00
Energy Storage

• Presentation of different types of energy storage systems (heat, mechanical and electrochemical);
• Definition of energy and power densities;
• Description of the operating principle of rechargeable batteries and their fundamental electrochemistry (lithium-ion batteries, lead-acid batteries, etc.);
• Definition of the electrical characteristics present in the data sheet of each electrochemical storage system;
• Description of the operating principle of conventional supercapacitors using the double layer capacitance theory;
• Presentation of the chemical constitution of hybrid supercapacitors such as lithium-ion capacitors;
• Description of aging mechanisms that may arise in different types of batteries and supercapacitors;
• Comparison of different energy storage systems using the Ragone Diagram;
• Presentation of electrical modeling methods of electrochemical energy storage systems;
• Presentation of power converters used with energy storage systems;
• Description of the tools integrated in management systems that aim to control energy storage systems;
• Presentation of an example of a complete system integrating an energy storage system, the corresponding management system and the power converters.

Lectures : 12h00
Tutorials : 12h00
Environmental Aspects of Energy

• Fundamental concepts of energy engineering: primary energy, final energy, embodied energy, lost energy, etc.
• Performance criteria used to assess existing systems or processes: efficiency, effectiveness, energy returned on energy invested (EROI), etc.
• Definitions and limitations of today's energy resources: peak oil, GHG emissions, etc.
• Carbon cycles and balances: why it is important and how to use them.
• The energy transition and its numerous challenges.

Lectures : 18h00
Exergy Analysis

• The exergy and anergy concepts and their relation with energy.
• Applications of exergy and energy balances to closed or open systems, housing or not internal reactive processes : heat engines, refrigeration machines, heat exchangers, internal combustion engines, HVAC systems;
• Exergy efficiency and effectiveness of energy systems;
• Environment, sustainability and use of natural resources, from the standpoint of exergy analysis.

Lectures : 8h00
Lab Work : 8h00
Power Systems

- Electrical AC grids.
- Electrical DC grids.
- Electrical safety measurements.
- Autonomous energy grid (smartgrid) sizing and control.

Lectures : 8h00
Tutorials : 8h00
Lab Work : 8h00
Industrial and Supply Chain Management Courses S8 12 Industry of the Future

• Understanding the challenges of the Digital Factory and the Digital Twin :
- convert an eBOM (engineering Bill of Materials) into a mBOM (manufacturing of Bill of Materials)
- make a process planning
- allocation of resources (machine tool operator, etc.)
• Analyse the product/process impacts and propose improvements
• To be able To manipulate robots virtually and physically
• Organisation and management of a production through a challenge in the "School Factory" platform



Lectures : 8h00
Tutorials : 12h00
Project : 28h00
Sustainable and Integrated Supply Chain

- CSCA certification (Certified Supply Chain Analyst): an international certification, recognize world wide within the world of Supply Chain
- Analyse the carbon footprint of a factory
- Warehouse Management System (WMS)
- Reverse Logistics
- Distribution Logistics and Transports

Lectures : 8h00
Tutorials : 24h00
Project : 28h00
Innovation project S8 10 Innovation Project

The core contents are all related to the developed skills aforementioned and follow the structure of the project.

Lectures : 27h00
Lab Work : 6h00
Project : 120h00
Mechanical Engineering courses S8 12 Heating, Ventilation and Air Conditioning HVAC

Lectures : 12h00
Tutorials : 8h00
Advanced Manufacturing & Processes

Integration of the digital chain in the preparation work. Cutting conditions for solid materials.
Optimization of the machining parameters (cutting conditions, CAM "Spirit", process studies, choice of tools ...).

Lectures : 2h00
Lab Work : 28h00
Hydraulics

- Minor (/ local) and major (/ friction) head losses formulations for viscous flows
- Presentation of head losses adding (/ coupling) laws: series coupling and parallel coupling head losses – Presentation of Electrical analogy and drawing of network characteristic curve
- Study of hydraulic networks and sizing of pumping systems and hydroelectric energy setups. Implementations of Generalized Bernoulli equation – Duty/operation point concept: selection of a pumping system adapted to a required flow rate in an existing hydraulic network
- Pump curve, Affinity laws, parallel and series operation
- Modification of the operating point
- NPSH and cavitation (available and required NPSH)
- Basics of Fluid power: generation, distribution, deployment, and regulation systems

Lectures : 12h00
Tutorials : 8h00
Tribology

1. Introduction
• Definition of Tribology and Tribological Systems
• Applications and Scales in Tribology
• Types of Motion
• Tribological Testing and Types of Tribometers
• Roughness
2. Lubrication and Lubricant Properties
• Classification of Lubrication and Lubricant Properties
• The Stribeck Curve and Lubrication Regimes
• Types of contacts and film thickness
• Hertzian Contact Theory
• Solid-Solid Contact-Asperity Deformation
3. Friction
• Friction Coefficient
• Types of Friction
• Laws of Dry Friction
• Basic Mechanisms of Sliding Friction
• Adhesion and Deformation
• Stick-Slip Phenomenon
4. Fluid Film Lubrication
• Classification of Fluid Film Lubrication
• Newtonian and Non-Newtonian Fluids
• 1-D Flow between Parallel Plates
• Hydrostatic and Hydrodynamic Thrust Bearings
5. Wear
• Parameters and Stages of Wear
• Wear Types and Mechanisms
• Wear Rate
• Causes of Wear and Prevention Methods

Lectures : 12h00
Tutorials : 8h00
Professional and Personal Development S8 4 Business Games

A conference-based format is scheduled.

Lectures : 21h00
Ethics

During the lectures, students will be introduced to basic theories and principles in ethics such as utilitarianism, relativism and deontology. The tutorials will be focused on ethical dilemmas from the areas of engineering in the program's pathway specializations.

Lectures : 6h00
Tutorials : 6h00
International Openness

The teaching unit 'International Openness' in semester 7 incorporates the following modules (not followed by all students):
Optional Foreign Language (different languages and level groups)
French Cultural Awareness
Interculturality 4

Lab Work : 32h00
Personal and Professional Development

Students will learn intercultural skills necessary for their departure during their 5th year of studies. They will also update their CVs and cover letters written during EENG1.

Tutorials : 12h00
Research Methods

Lectures and tutorials are given as follow :
-Lecture 1 : Introduction and tools for bibliographic research
-Tutorial 1 : Application of the methodology to find relevant research papers
-Lecture 2 : Analysis of literature review and introductions to the project phase
-Tutorial 2 : Cross analysis of a set of research papers
-Tutorial 3 and 4 : Project kick-start

-Autonomy sessions : redaction of a literature review.

Lectures : 4h00
Tutorials : 8h00
Project : 20h00
Robotics & IT Courses S8 12 Ethics for Robotics

-Introduction to ethics and ethical dilemmas
-Practical exercises on simple case studies
-Ethics and Autonomous systems and/or Robotics
-Applied ethics in Robotics
-Practical analysis of a chosen case study in Robotics

Lectures : 10h00
Tutorials : 2h00
Introduction to Controllers

-Definition of a PLC
-Hardware components of a PLC
-Connection of I/O modules
-Program a filling machine using Ladder, Function block, Structured text, Grafcet
-Train on data types, variables

Lab Work : 12h00
IT & Robotic Labs

The scrum methodology is introduced to the students. Then, they apply this agile framework during the whole duration of the project.
Each group of students receives a project of robotic application. They state the problem before designing the robotic system that corresponds to the specifications. Then, they build their system and test it extensively.
Finally, each group presents their work and write a report describing the technical and managerial aspects of the project.

Lab Work : 28h00
IT Expertise - Machine Learning

* Introduction to IA and Machine Learning
° Model Based Learning - main concepts and definitions
° Exact solution, iterative solutions, Gradient Descent
° First algorithms: Regressions
- Linear Regression
- Logistic Regression
° Data preprocessing
° Hyperparameter tuning

* Towards Deep Learning
° more on preprocessing (categories encoding) and data sets
° From biological neuron to perceptron
° Multilayer Perceptron
° Convolutional Neural Networks
° Transfer Learning

* Introduction to Natural Language Processing
° Some important ideas about NLP
° Example of statistical NLP (Multinomial Naive Bayes)
° NLP with Deep Learning (LSTM)

* Other algorithms

* Group project (text classification, image classification, recommendation, regression...)

Lectures : 8h00
Lab Work : 12h00
IT expertise - Machine Vision

-Introduction to camera features
-Introduction to the importance of lighting in image acquisition
-Introduction to various technologies in image acquisition
-Practical application on quality control, robot guidance and deep learning

Lectures : 4h00
Lab Work : 8h00
Robotic Expertise - Motion Planning & Control

-Definition of industrial networks: Ethercat, Profinet, OPC-UA, IO-Link…
-Practical on PLC/sensors/actuators communication using several industrial networks.
-Definition of safety regulations
-Procedure to perform risk analysis
-Definition of drive-based and controller-based motion planning followed by practicals

Lab Work : 12h00
Robotic Expertise - Automation & Industrial Robotics

This course divided into four parts. In the first part will give an overview of industrial robots basic components and structures. Part 2 depicts principles and methods of programming robots. Part 3 describes industry robotisation and robots workstations. The final part touches the safety of industrial robots and cobots.
In this course, we will explore Arm construction and drives, Coordinates systems (BASE • TOOL • TCP • Part frame/User frame/Working frame), programming methods (Online • Offline), Robotized workstations/cells, risk assessments of robotic cells and standardizations/normalizations.

• Introduction to industrial robotics
• Basic components of industrial robot systems
• Structure of industrial robots
• Collaborative, non-collaborative, and mobile industrial robot applications
• Industrial robot's motion
• Methods of programming robots
• Hazards associated with industrial robot applications
• Safety considerations for employers and workers
• Risk assessments
• Risk reduction measures
• Applicable industry standards for industrial robot system safety


Lectures : 6h00
Tutorials : 2h00
Lab Work : 12h00
Wireless Communications & Networks

-Introduction to IoT devices and their architectures (microcontroller, antenna…)
-Introduction to radio waves and principles of modulation (amplitude, frequency and phase)
-Definition of the various IoT networks (Short-range, LPWAN, Cellular)
-Practical case study to choose the best IoT solution given technical specifications
-Practical introduction to IoT programming with Sigfox modules for Arduino board

Lectures : 4h00
Lab Work : 8h00
Sustainable Management S8 1 Circular Economy

This course is an introduction to the circular economy concept. In this course, student will learn about the 7 pillars of the circular economy with many examples.

Lectures : 3h00
Project : 2h00
Innovation Management & Intellectual Property

- Innovation management for companies (different types)
- Intellectual property: patent deposit, management of patents
- General management of organizations for keeping the company's strategic advantages.

Lectures : 3h00
Project : 2h00
Sustainable Finance

Conference-based format dealing with the aforementionned topics.

Lectures : 3h00
Project : 2h00
SEMESTER 8 30 Pied de interne 3 Pied de interne 4 Pied de interne 5