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Learn the Basics of Electric Vehicles: A Beginner's Course

Name: Learn the Basics of Electric Vehicles: A Beginner's Course
Rating: 4.7 (247 reviews)

Accelerate Your Knowledge of Sustainable Transportation: A Comprehensive Guide to Electric Vehicles and Green Technology

Created byLogical Reasoning Online

Last updated 4/2023

English

What you'll learn

Understand the fundamentals of electric vehicles, including how they work, lifecycle analysis and their advantages over traditional gasoline-powered vehicles.
Identify the key components of an electric vehicle, including the battery, motor, and power electronics.
Explain the factors that affect the performance and lifespan of an electric vehicle battery, such as temperature, charging rate, and depth of discharge.
Understand the importance of recycling and proper disposal of used batteries, and identify the economic and environmental benefits of battery repurposing.
Describe government policies and incentives for promoting the adoption of electric vehicles and reducing the environmental impact of transportation
Recognize the future trends in electric vehicle technology, including the development of solid-state batteries, wireless charging, and integration of renewable.
Understand the differences between owning and maintaining an electric vehicle versus internal combustion vehicle, including expertise required for EVs.,
Evaluate the potential of electric vehicles to transform transportation and contribute to a more sustainable and eco-friendly future.

Course content

13 sections • 43 lectures • 1h 59m total length

What are Electric vehicles1:41
Explore what electric vehicles are, how they differ from traditional cars, and their advantages, disadvantages, and history, while noting charging options and battery progress.
Brief History of Electric Vehicles2:22
Trace the electric vehicle's journey from 1830s origins to modern advances in lithium ion batteries and charging infrastructure, highlighting milestones, shifts in popularity, and ongoing global adoption.
Types of Electric Vehicles1:44
Learn three types of electric vehicles: battery electric, plug-in hybrid, and hybrid. See BEVs run on electricity, PHEVs offer 20–50 miles of range, and HEVs charge without external power.
Differences between Electric and Gasoline Vehicles1:38
Electric vehicles use a battery-powered motor, while gasoline vehicles rely on an internal combustion engine. They are more efficient and have zero tailpipe emissions, though battery replacement can be costly.
Advantages and disadvantages of Electric Vehicles1:28
Compare the advantages and disadvantages of electric vehicles, highlighting lower operating costs, fewer emissions, and smoother, quieter driving, against higher upfront costs, limited range, and variable charging infrastructure.
Overview of main Components in Electric Vehicles vs. Internal Combustion Engine6:05
Compare electric vehicles with combustion engines by examining motors, batteries, inverters, controllers, and charging systems versus combustion engine components, and understand environmental and cost implications for informed vehicle choices.
Knowledge Checkpoint for lesson 1

Comparison of emissions from Electric Vehicles and combustion engine vehicles3:07
Lifecycle analysis of Electric Vehicles2:32
Impact of Electric Vehicles on reducing greenhouse gas emissions3:30
Explore how electric vehicles can cut greenhouse gas emissions, potentially by up to 1.5 gigatonnes of CO2 per year by 2030, driven by policies, market developments, renewables, and charging infrastructure.
Knowledge Checkpoint for Lesson 2

Types of batteries used in Electric Vehicles3:06
Explore the electric vehicle battery system, compare lithium ion, nickel metal hydride, and lead acid options, explain charging methods, and cover evolving solid-state battery technologies and the battery management system.
Battery chemistry and construction2:58
Learn how lithium ion batteries power electric vehicles by moving ions between lithium cobalt oxide positive electrode and graphite negative electrode through an electrolyte to prevent short circuits.
Battery Selection and Sizing2:51
Select the right battery chemistry, size, and capacity to meet a system's power and energy needs, considering energy density for range and performance.
Battery Management System2:52
Battery management system monitors voltage, current, and temperature to manage lithium-ion batteries, prevent overcharge and over-discharge, guard against thermal runaway, inform drivers of charge and range, and guide charging routes.
Knowledge Checkpoint for lesson Lesson 3

Types of Electric Motors2:54
Explore how electric motors and drivetrains propel electric vehicles, and compare ac motors, dc motors, and induction motors by efficiency, cost, power output, and typical use cases.
Operating principles of Electric Motors2:12
Components of an Electric Drivetrain2:29
Identify the key components of an electric drivetrain: motor, battery pack, power electronics, and transmission, and explain how the motor's rotor, stator, and controller regulate speed and torque.
Differences between Electric vs Internal Combustion Engine Drivetrain2:44
Electric drivetrains deliver higher efficiency and torque with seamless power delivery and lower maintenance than traditional internal combustion engine drivetrains, boosting range and overall driving performance.
Knowledge Checkpoint for lesson Lesson 4

Power Conversion3:32
Discover how power electronics convert high voltage dc from the battery pack to low voltage dc and then to low voltage ac for the motor, and learn regenerative braking benefits.
Regenerative Braking2:52
Explore regenerative braking in electric vehicles, where the motor acts as a generator to recapture energy during braking, store it in the battery, and improve efficiency, range, and brake longevity.
Energy Management Systems2:58
Master energy management systems in electric vehicles by monitoring the state of charge, regulating motor and power electronics to optimize energy use, and maximizing regenerative braking to extend range.
Knowledge Checkpoint for lesson Lesson 5

Characteristics of Electric Vehicle Dynamics2:27
Electric vehicles deliver instant torque from the motor, enabling rapid acceleration and strong passing power, with a lower center of gravity that enhances handling and provides a smoother, quieter ride.
Motor Control Strategies3:25
Explore motor control strategies that manage torque output in electric vehicles. Study field oriented control, direct torque control, and maximum torque per ampere.
Vehicle Stability Control and Traction Control2:33
Explore how vehicle stability control and traction control safeguard electric vehicles by monitoring sensors, regulating motor torque, and applying brakes to maintain traction and stability.
Knowledge Checkpoint for lesson Lesson 6

Factors affecting electric vehicle range3:33
Explore how driving behavior, temperature, wind resistance, and auxiliary systems affect electric vehicle range and performance. Compare energy management with internal combustion engines and learn planning tips for maximizing range.
Battery capacity and energy consumption1:53
Electric vehicle efficiency and energy management2:49
Understand how electric vehicle efficiency and energy management affect performance and range, with regenerative braking and energy recovery optimizing use while limiting auxiliary loads like air conditioning.
Knowledge Checkpoint for lesson Lesson 7

Definition of Well-to-Tank energy efficiency2:45
Calculation of Well-to-Tank efficiency for gasoline and electric vehicles1:39
Calculate well-to-tank efficiency for gasoline and electric vehicles by accounting for energy inputs and outputs from crude oil extraction through refinery, transport, and fueling or electricity transmission.
Factors that affect Well-to-Tank efficiency2:41
Knowledge Checkpoint for lesson Lesson 8

Definition of Tank-to-Wheel energy efficiency2:57
Define tank-to-wheel energy efficiency and examine how drivetrain losses affect electric and internal combustion vehicles. Compare 12–30% ICE efficiency with 60–90% EV efficiency and relate to weight, aerodynamics, and performance.
Calculation of Tank-to-Wheel efficiency for gasoline and electric vehicles2:19
Factors that affect Tank-to-Wheel efficiency2:41
Explore factors affecting tank-to-wheel efficiency—weight, aerodynamics, driving behavior—and how lightweight materials and features like active grille shutters and underbody panels reduce energy use.
Knowledge Checkpoint for lesson Lesson 9

Types of Charging Stations4:09
Explore the three ev charging types: level one, level two, and dc fast charging, and their speeds, use cases, and installation considerations.
Connectors1:13
Learn about vehicle connectors, including j1772 and CCS, and how level one, level two, and DC fast charging differ. Check connector compatibility and adapters to ensure safe, efficient charging.
Charging Station Locations and Networks3:24
Home Charging Options and Installation2:07
Knowledge Checkpoint for lesson Lesson 10

Requirements

No engineering experience? No problem! Our course on electric vehicles and future trends is accessible to anyone with an interest in sustainability and cutting-edge technology. Whether you're a die-hard gearhead or just curious about the future of transportation, our course is open to all, with no prerequisites or technical expertise necessary.

Description

“Learn the Basics of Electric Vehicles: A Beginner's Course” is the only course you need to learn! From the history and evolution of electric vehicles to the current state of the market and the latest technological advancements, this course covers everything you need to know about electric vehicles.

This electric vehicle course is undoubtedly the most comprehensive electric course available anywhere online, whether you're a student, professional, or just curious about the technology. A solid foundation in the fundamental concepts is essential for success in the electric vehicle industry. That's why this electric vehicle course is designed to be accessible to anyone, regardless of your background or without requiring an extensive technical background.
For students, this course provides a strong foundation in the basics of electric vehicles, including the history, science, and benefits. You'll gain a comprehensive understanding of the technology, making informed decisions about future career paths.
Professionals in the transportation field will appreciate this course's ability to provide the foundational knowledge needed to understand the concepts of electric vehicles without requiring an extensive technical background. Learn about the lifecycle analysis of electric vehicles, identify various types, and understand the infrastructure and best practices needed to maintain and operate them. By the end of the course, you'll be well-equipped to lead your team in developing and implementing zero-emission projects.
For those interested in pursuing a career in the electric vehicle industry, this course is the perfect starting point. Learn about the skills and knowledge required to succeed in this rapidly growing industry. You'll gain a great understanding of the electric vehicle landscape and be prepared to take your first steps into the field.
Finally, for regular drivers who are curious about electric vehicles, this course offers a comprehensive understanding of how electric vehicles work, their benefits for everyday driving, and the best practices for maintaining and operating them. You'll be well-equipped to make the switch to an electric vehicle yourself.

Don't miss out on the opportunity to learn the course from industry expert instructor and gain a comprehensive understanding of electric vehicles. Start your journey towards a sustainable future with the course today! Here is Why?

The course has been updated to be 2023 ready and you'll be learning the latest tools and technologies.
The curriculum was developed over 1 year, with comprehensive student testing and feedback from the various leading Universities in California to develop a future workforce in the clean transportation field.
You will get a chance to put your knowledge to the test. The quiz at the end of each lesson is developed to reinforce your learning and ensure you have a solid understanding.
The course is constantly updated with new content, with new modules determined by students - that's you!

With 2 hours of HD video tutorials, you'll build your knowledge with real-life explanations and plain English pronunciation, making it accessible to anyone worldwide. Say goodbye to boring lectures and hello to engaging content that will leave you eager to learn more!

Throughout this comprehensive course, we cover a massive amount technologies, as follows:

I. Introduction of the Course

A. Welcome

B. Who Should Attend?

C. Course Outline?

D. What Does this Course Not cover?

1. Introduction to Electric Vehicles

A. Definition of Electric Vehicles

B. Brief history of Electric Vehicles

C. Types of Electric Vehicles

D. Differences between Electric and ICE Vehicles

E. Advantages and disadvantages of Electric Vehicles

F. Main Components in Electric Vehicles vs. Internal Combustion Engine (ICE) Vehicles

2. Environmental Impact of Electric Vehicles

A. Comparison of emissions from Electric Vehicles and combustion engine vehicles

B. Lifecycle analysis of Electric Vehicles

C. Impact of EVs on reducing greenhouse gas emissions

3. Battery System

A. Types of batteries used in Electric Vehicles

B. Battery chemistry and construction

C. Battery Selection and Sizing

D. Battery Management System

4. Electric Motors and Drivetrain

A. Types of Electric Motors

B. Operating principles of Electric Motors

C. Components of an Electric Drivetrain:

D. Differences between Electric Drivetrains and Traditional Internal Combustion Engine Drivetrains:

5. Power Conversion and Regenerative Braking

A. Power Conversion

B. Regenerative Braking System

C. Energy Management Systems

6. Vehicle Dynamics and Control

A. Characteristics of Electric Vehicle Dynamics

B. Motor control strategies

C. Vehicle stability control and traction control

7. Electric Vehicle Performance and Range

A. Factors affecting electric vehicle range

B. Battery capacity and energy consumption

C. Electric vehicle efficiency and energy management

8. Well-to-Tank (WTT) Energy Efficiency

A. Definition of Well-to-Tank energy efficiency

B. Calculation of WTT efficiency for gasoline and electric vehicles

C. Factors that affect WTT efficiency

9. Tank-to-Wheel (TTW) Energy Efficiency

A. Definition of Tank-to-Wheel energy efficiency

B. Calculation of TTW efficiency for gasoline and electric vehicles

C. Factors that affect TTW efficiency

10. Electric Vehicle Charging and Infrastructure

A. Types of Charging Stations, Charging Time and Speed

B. Types of Connectors

C. Charging Station Locations and Networks

D. Home Charging Options and Installation

11. Battery Life, Replacement and Recycling

A. Factors Affecting Battery Life and Replacement

B. Recycling and Disposal of Used Batteries

12. Electric Vehicle Industry and Future Trends

A. Government policies and incentives for Electric Vehicles

B. Future trends in Electric Vehicle technology

C. Electric Vehicle ownership and maintenance

13. Conclusion

A. Key takeaways

So, what are you waiting for? Click the buy now button and join the world's best beginner Electric Vehicle course to start your journey to becoming an electric vehicle expert!

Who this course is for:

Anyone interested in staying up-to-date with the latest developments in the electric vehicle industry, including battery technology, charging infrastructure, government policies, and future trends, will benefit from this course's comprehensive and informative content.
Managers who are leading zero-emission projects in their companies will learn about government policies and incentives for electric vehicles and energy efficiency, helping them make informed decisions that promote sustainability.
Individuals looking to start a new career in the electric vehicle field will acquire a solid foundation of knowledge, including the basics of electric vehicle technology and maintenance, industry trends, and future developments.
This course is ideal for regular drivers who want to transition to electric vehicles and learn best practices for ownership and maintenance, reducing their carbon footprint and promoting sustainability.
Learners interested in reducing their environmental impact and mitigating climate change will gain valuable insights into the role of renewable energy and green technology in the transportation sector.

Learn the Basics of Electric Vehicles: A Beginner's Course

What you'll learn

Explore related topics

Course content

Introduction to Electric Vehicles6 lectures • 15min

Environmental Impact of Electric Vehicles3 lectures • 9min

Battery System4 lectures • 12min

Electric Motors and Drivetrains4 lectures • 10min

Power Conversion and Regenerative Braking3 lectures • 9min

Vehicle Dynamics and Control3 lectures • 8min

Electric Vehicle Performance and Range3 lectures • 8min

Well-to-Tank (WTT) Energy Efficiency for electric vehicles3 lectures • 7min

Tank-to-Wheel (TTW) Energy Efficiency3 lectures • 8min

Electric Vehicle Charging and Infrastructure4 lectures • 11min

Requirements

Description

Who this course is for: