About the Program
Building and simulating a vehicle model enables the engineers to analyse several power train configurations and determine if requirements are met for each design. If engineering requirements are not met by a power train configuration, it is much easier to change a parameter in a computer model than it is to make a change to a vehicle prototype that is already built. For example, it is easy to change the power rating of an electric motor in a computer model, but we know it can be challenging to swap motors in a real vehicle. Engineers can study the performance and energy consumption aspects of a power train configuration from a vehicle model. Finally, let’s not forget that running computer simulation is faster and more cost effective than building and driving an actual vehicle prototype (90’s model)
Technologies and Tools Covered
- Matlab Simulink and simscape
- Motor control design with Matlab and Simulink
- Modelling batteries using Simulink and simscape
- Battery cell balancing and state of charge system estimation
- Battery thermal management system
- Electric vehicle control system
- Inverter and converter
 LEARNING PATH
Matlab Simulink
Introduction to the Simulink graphical programming environment for modeling, simulating, and analyzing dynamic systems, and familiarizing tools.
|
SESSION |
CLASS TOPICS |
| 1.      | Introduction for Simulink and Simscape |
| 2.      | Introduction for electric vehicle |
| 3.      | Overview of tools handling |
| 4.      | Types of EV and motors used for EV |
| 5.      | Introduction for PMSM motor and dc motor |
Motor control and designing using Matlab
 The electric motors used for automotive applications should have characteristics like high starting torque, high power density, good efficiency The rapid development in the field of power electronics and control techniques has created a space for various types of electric motors to be used in Electric Vehicles.
|
SESSION |
CLASS TOPICS |
| 1.      | Speed control of motors and Motor driver |
| 2.      | Inverter, converter concept and application |
| 3.      | Simulink design for inverters and converter |
 Battery Management
 Discussion of types of storage elements for electric vehicles and the characteristic study improves the total efficiency of system.
| SESSION | CLASS TOPICS |
| 1 | Introduction to battery, and its characteristics |
| 2 | State of charge estimation of battery |
| 3 | Battery thermal management system design |
| 4 | Question and Answers |
Projects & Assignments
Practical 1: Familiarization of Simulink tools
Practical 2: Motor design, and its control
Practical 3: Electric vehicle design and control
Practical 5: Chopper design and control, inverter design and control
Training Methodology
The Program is mix of Theory sessions, Quizzes, Hands on Sessions, Liver Interaction with Experts, Assignments and Practical Exercises. Maximum Impetus is given to Hands on Sessions so as to enable the participants with the maximum knowledge transfer and satisfaction. The ratio of the theory, practical sessions will be 30:70.
Program Advantage
·      Code with Explanations
Learn everything about Electric vehicle design and the Matlab Simulink, with a well-structured curriculum & detailed explanations.
·      Assignments
Work on various assignments which will be graded by our Trainer.
·      Projects
Solve real world problems as part of projects and receive valuable feedback from our trainer.
Upon Successful Completion of the Program
Upon completion of the program, the participant will have an in-depth insight into the electric vehicle technology modelling in Simulink environment. The participants will be able to program the controller and develop basic / complex applications on his own, thus making the objective of the training program as desired.
Participants also will have access to our TECHNICAL FORUM, thus getting their doubts clarified even after the session is complete. Certificates will be provided upon request.
