Introduction to Hybrid and Electric Vehicles

Module 1: History of Electrical Vehicle

Lecture 1: Introduction to Hybrid Electric Vehicles [Page 01 to 09]

Lecture 2: Economic and Environmental Impact of Electric Hybrid Vehicle [Page 10 to 18]

M1

Module 2: Dynamics of Electric and Hybrid vehicles

Lecture 3: Motion and dynamic equations for vehicles [Page 01 to 14]

Lecture 4: Vehicle Power Plant and Transmission Characteristics [Page 15 to 28]

M2

Module 3: Architecture of Hybrid and Electric Vehicles

Lecture 5: Basic Architecture of Hybrid Drive Trains and Analysis of Series Drive Train [Page 01 to 10]

Lecture 6: Power Flow in HEVs [Page 11 to 19]

Lecture 7: Torque Coupling and Analysis of Parallel Drive Train [Page 20 to 33]

Lecture 8: Basic Architecture of Electric Drive Trains [Page 34 to 43]

M3

Module 4: DC-DC Converters

Lecture 9: DC-DC Converters for EV and HEV Applications [Page 01 to 14]

Lecture 10: Boost and Buck-Boost Converters [Page 15 to 23]

Lecture 11: Multi Quadrant DC-DC Converters I [Page 24 to 32]

Lecture 12: Multi Quadrant DC-DC Converters II [Page 33 to 40]

Lecture 13: DC-DC Converters for EV and HEV Applications [Page 41 to 55]

M4

Module 5: DC-AC Converters

Lecture 14: DC-AC Inverter for EV and HEV Applications [Page 01 to 10]

Lecture 15: Three Phase DC-AC Inverters [Page 11 to 23]

Lecture 16: Voltage Control of DC-AC Inverters Using PWM [Page 24 to 34]

M5

Module 6: A.C. Electrical Machines for Hybrid and Electric Vehicles

Lecture 17: Induction motors, their configurations and optimization for HEV/EVs [Page 01 to 13]

Lecture 18: Induction motor drives, their control and applications in EV/HEVs [Page 14 to 26]

Lecture 19: Permanent magnet motors, their configurations and optimization [Page 27 to 36]

Lecture 20: Permanent magnet motor drives, their control and applications in EV/HEVs [Page 37 to 55]

Lecture 21: Switch reluctance motors, their configurations and optimization [Page 56 to 65]

M6

Module 7: Permanent Magnet Machines for Hybrid and Electric Vehicles

Lecture 22: Permanent Magnet Motors [Page 01 to 12]

Lecture 23: Steady State Characteristics of Permanent Magnet Motors [Page 13 to 19]

Lecture 24: Dynamic Model of PM Machines [Page 14 to 32]

Lecture 25: Control of PM machines [Page 33 to 44]

Lecture 26: Flux Weakening Control of PM machines [Page 45 to 54]

M7

Module 8: Design of Hybrid and Electric Vehicles

Lecture 27: Design Principles of HEVs I [Page 01 to 09]

Lecture 28 Design Principles of HEVs II: [Page 10 to 18]

Lecture 29: Drive cycle and its detailed analysis [Page 19 to 31]

Lecture 30: Sizing of Electric Machine for EVs and HEVs [Page 32 to 40]

M8

Module 9: Energy Storage

Lecture 31: Batteries [Page 01 to 14]

Lecture 32: Mathematical Modeling for Lead acid battery [Page 15 to 28]

Lecture 33: Alternative and Novel Energy Sources [Page 29 to 36]

Lecture 34: Fuel Cell [Page 37 to 51]

M9

Module 10: Control System for Electric and Hybrid Electric Vehicles

Lecture 35: Control Systems for the HEV and EVs [Page 01 to 09]

Lecture 36: The Hybrid ECU and Its classification [Page 10 to 21]

Lecture 37: The Fuzzy Logic Based Control System [Page 22 to 31]

M10

Module 11: Regenerative braking

Lecture 38: Fundamentals of Regenerative Braking [Page 01 to 08]

Lecture 39: Brake System of EVs and HEVs [Page 09 to 19]

M11

Module 12: Design of Hybrid Electric vehicles

Lecture 40: Design of HEVs A Primer [Page 01 to 08]

Lecture 41: Design of Series HEV [Page 09 to 17]

Lecture 42: Examples of Design of Series HEV and Parallel [Page 18 to 28]

Lecture 43: Design of Series-Parallel HEV Drivetrain [Page 29 to 44]

M12