
Explore the core architecture of electric vehicles, detailing the drive train, battery, and motor, how charging converts AC to DC, and how regenerative braking affects range.
Explore the history of electric vehicles from 19th-century origins to the present, highlighting global evolution and the emergence of India's electric mobility landscape with companies like Tata and Mahindra.
Explore the four major types of electric vehicles—hybrid, plug-in hybrid, battery electric, and fuel cell—and learn their architectures, components, and how battery power drives the motor.
Learn to compute motor torque and power for electric vehicles, accounting for rolling resistance, grade resistance, acceleration, and aerodynamic drag across drivetrain configurations.
Explore how lithium ion cells store chemical energy and convert it to electricity via cathode, anode, and electrolyte, and review chemistries like NMC, NCA, LFP, and LTO.
Learn to design electric vehicle battery packs by configuring cells in parallel and series (mpns) to meet target voltage and capacity, with practical calculations using 21700 cylinders.
Explore the electrical design of battery packs for modern electric vehicle systems, integrating pack architecture with full electric vehicle system considerations.
Discover how to optimize thermal management within modern electric vehicle systems to maintain performance, safety, and reliability across varied operating conditions.
Explore the battery management system (BMS) in modern electric vehicle systems. Gain insights into its role in electrified vehicle architectures.
Gain hands-on experience in battery pack design within electrified modern electric vehicle systems, exploring practical approaches to create reliable and efficient packs for contemporary EVs.
Delve into electric vehicle charging systems with a focus on the electric vehicle charger-2 module, advancing understanding of modern ev charging infrastructure and components.
Master electric vehicle charger-4 within the electrified mastering modern electric vehicles systems course, and gain insight into how this charger fits into contemporary electric vehicle architectures.
Learn the testing requirements for electric vehicles and battery packs under AIS-038 and AIS-156, covering vehicle level and battery pack tests, protection against electrical shock, direct and indirect contact.
Electrified: Mastering Modern Electric Vehicles Systems
Here is a snapshot of the roadmap we’ll be following:
The Architecture: The complete overview of electric vehicle architecture whether it is a two wheeler, three wheeler or a four wheeler. We will see the conversion of a ICE vehicle to Electric Vehicle
The Drivetrain: We will know the types of drivetrain used in the electric vehicle industry and with the different motors used in the electric vehicle industry. We will know the calculation of motor torque and power required for a particular EV.
The Powerhouse: Mastering the electric vehicle battery pack design from all the electrical, mechanical and thermal aspects along with the battery management system.
Thermal Management: How modern EVs keep their cool under pressure. Different types of cooling methodology used in electric vehicles. The thermal runaway of the battery pack and major cause of this. Heat load calculation of a battery pack.
Battery Management System: How the BMS plays a vital role to monitor and control the EV battery pack. The SoC and SoH estimation.
The Chargers: You need it somewhere to recharge the Battery pack. We will go through different types of chargers, wireless chargers, V2X and a basic design of an EV charger.