EXPLORE OUR CATALOGUE TO MAKE YOUR PERSONAL SKILL PROGRAM
4–6 hours
On demand (Business)
2–4 hours
On demand (Business)
Thanks to the ebooks, students will be able to rediscover the basics of certain courses and deepen their knowledge of others.
This module consists of two sections:
1. Exploring Options
2. Making My Choice
To access section 2 and select your option, you must first complete section 1 and achieve a minimum correct answer rate of 70% on all quizzes.
The deadline to complete this module and make your choice is November 3rd.
Please understand that completing this module is the only way to make your choice for PSM 2024, and it is mandatory.
Plan to dedicate 20 to 30 minutes to complete the entire module.
Thanks to the ebooks, students will be able to rediscover the basics of certain courses and deepen their knowledge of others.
Thanks to the ebooks, students will be able to rediscover the basics of certain courses and deepen their knowledge of others.
Thanks to the ebooks, students will be able to rediscover the basics of certain courses and deepen their knowledge of others.
Upon completion of this unit, students should be able to:
- Apply basic knowledge of power electronic into the definition of an electric powertrain.
- Use common definitions in the field of power electronics.
- Describe all system architectures.
- Examine the operating mode, life cycles, aging and safety aspects of power electronics.
- Show the main stages in design and manufacturing process of power electronics.
Upon completion of this unit, students should be able to:
- Demonstrate the electrochemical principles that explain the behavior of a battery cell.
- Use common battery definitions.
- Examine the operating mode, life cycles, aging and safety aspects of batteries.
- Illustrate the main stages in battery manufacturing and recycling.
- Justify technical specifications and design trade-offs.
- Describe different storage system architectures.
- Design the algorithm and hardware of a BMS.
- Roadmap of batteries: overview of the technological evolution (types of cathodes/anodes, types of electrolytes, materials, recyclability, architectures, etc.).
- Produce and operate a test plan for the evaluation and validation of storage systems.
Upon completion of this unit, students should be able to:
- Analyze main powertrain components.
- Evaluate advantages and disadvantages of different architectures in terms of performance, efficiency, and cost.
- Design, develop and test safe reliable powertrain systems, with a focus on a dysfunctionality and reducing risks to users and environment.
- Integrate emerging technologies into powertrains.
Upon completion of this unit, students should be able to:
- Design, model and simulate different types of electric machines in the mobility sector.
- Draft and negotiate technical specifications of electric machines.
- Manage trade-off between design and manufacturing process for electric machines.
- Use the operating principles to design the architecture of electric machine cooling circuits.
- Perform and negotiate electrical drive system trade-offs.
- Simulate electrical and thermal aspects of an electric machine and perform the tests to validate the calculations.
- Define and manage test plans for the evaluation & validation of electrical machine components.
At the completion of this course, students must be able to:
- Select topology and size power components such as power modules, capacitors, busbars, filtering.
- Desing, model and simulate power electronics for electric drives.
- Draft technical specifications of power electronics.
- Decide about the trade-off to be made during design of power electronics.
- Perform the pre dimensioning of cooling system for diverse power electronic architectures.
- Define and operate tests plans for the evaluation and validation of power electronics components.
- Integrate EMC constraints and dysfunctions into the design and validation phase.
Upon completion of this unit, students should be able to:
- Design, model and simulate an electrical energy storage system.
- Make architectural choices.
- Pre-dimension of a storage system cooling circuit.
- Perform electrical and thermal simulation of batteries.
- Analyze aging mechanisms and degradation factors at cell level.
- Integrate the consequences of aging phenomena on cell performance and on battery use.
- Desing an optimal accelerated aging experiment.
- Identify the structure of the cell aging model and calibrate its degradation rate law.
- Use the aging model on the scale of a battery with electrothermal coupling to assess durability for a given application.
- Produce and operate a test plan for the evaluation and validation of storage systems.
Upon successful completion of this course, students will be able to:
- Use the basic concepts of data science to solve challenging problems in e-Powertrains.
- Identify the technical and organizational enabler of big data.
- Use the basic concepts of artificial intelligence and machine learning to produce supervised, unsupervised, and reinforced learning algorithms.
- Apply machine learning techniques such as regression, classification, clustering, neural networks to solve automotive engineering problems.
- Analyze the applications and capabilities of AI and ML in the field of electric powertrain design.
- Use AI and ML to study, optimize, design and model electric powertrains considering constrains and performances targets.
- Explore predictive modeling techniques to predict the behavior and performance of electric powertrains using historical and real-time data.
- Analyze special use cases.
Continuation of the Lodève basin field course - From basin to reservoir (Oct. 16-21, 2022
-> From outcrop to model, now !
This independent module in 2 parts aims to present the LCA approach applied to Axens services and products. It provides the keys to know and understand LCA as an approach, to know how it fits into the project management with customers, and to be able to see the advantages/uses and the limits of the tool.
At the end of it, you will be able to:
- Explain how LCA works and its main principles
- Detail the main steps and their objectives
- Determine when and how to implement an LCA approach in their projects
- Find the necessary information on the relevant regulations
- Find the important information in an LCA report
This first part gives you an general introduction to the LCA approach
<2hours
Objectifs : ...
<2hours
On demand (Business)