Electric Vehicle Course with Guaranteed Placement

Electric Vehicle or EV is not just the future - it’s the present! With governments promoting green energy and companies investing billions in EV technology, the industry is set to create 10 million direct and 50 million indirect jobs by 2030. This as a result has increased the demand for skilled EV professionals. If you’re looking to build a career in this fast-growing field, now is the time to upskill with Internshala’s job-oriented Electric Vehicle course!

Internshala’s online Electric Vehicle (EV) course helps you learn everything from the basics to advanced EV technologies in a simple and structured way. You’ll start by learning about key EV components like motors, batteries, and powertrains, then move on to electric systems, infrastructure, and safety standards. 

Through hands-on projects, you'll use MATLAB for modeling and simulation. You’ll also explore power electronics, embedded systems, motor control, and learn about hybrid and ICE vehicle simulation. Additionally, you’ll gain insights into structural analysis using ANSYS and advanced charging system modeling.

Electric Vehicle Online Course Outline

This online EV course will provide you with a complete understanding of EV technology, along with an in-depth study of its design and systems. Whether you're taking your first steps into the EV industry or looking to expand your existing expertise, this structured curriculum will help you build the skills needed to succeed. Here’s what you’ll learn through this course:

Electric Vehicle Engineering 

• This module starts with the basics of EV technology and how it has evolved from traditional vehicles. You’ll explore market trends and new developments in EV design.
• In the next section, you'll dive into core EV components, including advanced battery systems, electric motors, power electronics, and vehicle electrification techniques.
• The third section of this module covers EV infrastructure, planning, and retrofitting—teaching both the technical and business aspects of converting traditional vehicles into EVs.
• The fourth section of this module will introduce you to business management in the EV industry, covering essential concepts along with key market insights.
• This module concludes with an in-depth explanation of EV testing and homologation where you will explore safety certifications, performance validation, and regulatory compliances. 

EV Advanced: Battery, Motor & Charging Dynamics 

• This module of the EV course will introduce you to EV performance analysis. You will learn how to calculate energy consumption, the size of batteries, and measure motor efficiency using numerical analysis. This module also explores hybrid electric vehicle (HEV) technologies, giving you insights into their applications and benefits in the EV industry.
• The second section of this module will cover safety standards and regulatory compliance. You will study the global safety protocols that ensure EVs meet industry regulations. This includes learning about battery safety measures, vehicle testing, and certifications required for different markets.
• The next section of this module will take you through the manufacturing and assembly of EVs. You will understand the entire production process, from building EV components to final vehicle assembly. This module also covers supply chain management, focusing on sourcing essential raw materials like lithium and cobalt, managing supplier networks, and optimizing logistics for cost efficiency.
• The final section of this module is designed for students looking to develop expertise in the EV industry. It offers deeper insights into industry trends, cutting-edge technologies, and career pathways in electric mobility.

MATLAB-SIMULINK: Design & Control Systems 

• The first section of this module will introduce you to MATLAB fundamentals. You will learn about its user interface, basic syntax, and data visualization techniques. Once you grasp the basics, you will move on to intermediate and advanced functionalities, including handling large datasets and writing efficient code.
• In the next section, you will focus on designing and developing data-driven projects using MATLAB. You will also learn how to create compelling visualizations using MATLAB’s plotting tools, customize graphs, and build interactive dashboards to present data insights effectively.
• The third section of this module introduces MATLAB-SIMULINK. You will learn how to use Simulink to build system models, simulate dynamic systems, and apply the Quantized State Systems (QSS) Toolbox for efficient simulation of complex systems.
• In the final section, you will explore advanced MATLAB tools for modeling, analysis, and optimization. You will also learn how to evaluate system designs and improve simulation performance, preparing you for real-world engineering challenges.
• Project: By the end of this module, you will build a complete EV system model in MATLAB/Simulink, focusing on key components like the battery and drivetrain. You will analyze energy efficiency, drive cycles, and battery integration to enhance vehicle performance.

Power Electronics & Circuit Design using Proteus & Altium

• This module of the online EV course begins with an introduction to the fundamentals of power electronics, including key parameters, performance metrics, and semiconductor technology. You will learn how to optimize the performance of power electronic devices and systems.
• The next section of the module explores power electronics systems and control. You will study converters, inverters, and control systems while understanding their role in renewable energy, electric vehicles, and power grids.
• The third section of this module will focus on circuit design and simulation using Proteus and MATLAB-SIMULINK. You will gain hands-on experience in creating schematic diagrams, simulating circuit behavior, analyzing performance, and troubleshooting power electronic systems.
• The final section will cover circuit design and prototyping using Altium Designer. You will learn how to create detailed schematics, design analog and digital circuits, and work on PCB layout, simulation, and analysis.

• Project: After mastering the core concepts of this module, you will apply your knowledge to design and simulate high-voltage circuits, such as converters and inverters, for EV applications. You will use MATLAB for system-level simulations and Altium Designer for PCB prototyping, gaining hands-on experience in both simulation and hardware design.

NOTE: After completing this section, your understanding will be evaluated through a mid-term viva worth 300 marks. The score will contribute to your final evaluation.

Embedded Systems: Embedded C, Microcontrollers, Arduino & Simulations

• The first section of the module introduces embedded systems, their structure, and applications. You will explore the 8051 Microcontroller, its components, core functions, instruction set, and programming techniques.
• In the second section of the module, you will learn Embedded C to program microcontrollers and develop applications. You will also study communication protocols like serial, wireless, and wired communication, which enable data exchange between embedded devices.
• The next two sections focus on Arduino development and  IoT applications. You will set up Arduino boards, write basic programs, and gradually move to advanced techniques for optimizing Arduino-based embedded systems. You will also explore IoT applications using Arduino, where you will build practical projects like home automation and environmental monitoring systems.
• Project: To practice what you’ve learned in this module, you will work on a project to design an IoT-based system for monitoring EV parameters like battery status and location. Additionally, you will set up a wireless communication system for data transmission and control using Arduino. 

Advanced Embedded Systems using ARM Cortex

• In the first section, you will learn how to interface LEDs, LCDs, and user input devices like switches and buttons with ARM-based microcontrollers. By the end of this section, you will be able to process user inputs and display information on devices like seven-segment displays.
• Next, you will dive into ADC programming and timer systems using STM32 microcontrollers. You'll explore advanced ADC techniques and timer-based operations, which are key for controlling analog signals in real-world applications.
• In the next section, you will explore the implementation of key communication protocols—UART, I2C, and SPI—on STM32 microcontrollers. This section also focuses on developing motor control signals for applications like robotics, automation, and electric vehicles.
• The last section will explore the implementation of Real-Time Operating Systems (RTOS) on STM32-based systems. You will learn how to design and develop charging control systems using ARM Cortex. It also teaches you how to develop a Smart Battery Management System (BMS) using ARM Cortex.
• Project: After completing this module, you will develop EV applications through embedded systems, including ADC programming, motor control, and RTOS implementation, using STM32 ARM Cortex microcontrollers. The project focuses on optimizing real-time performance and hardware interfacing.

Advanced EV Design & Simulations with MATLAB & Simscape

• The first section of this module will teach you how road conditions and load calculations impact electric vehicle systems. You will learn how aerodynamics and air drag influence vehicle performance and how to evaluate and optimize vehicle performance.
• In the second section of this module, you will discover the principles of motor design and effective control strategies. You will explore the use of Pulse Width Modulation (PWM) for motor control, covering signal generation, modulation techniques, and motor applications.
• The third section of this module helps you understand energy storage and fault analysis. You will explore ultracapacitor characteristics such as charge/discharge rates and energy density, as well as how to apply simulation techniques. You will also learn how to detect and analyze faults in battery packs.
• In the final section of this module, you will explore hybrid and ICE vehicle simulation. This section teaches you how to analyze and simulate hybrid vehicles for better efficiency.
  
  
• Project: At the end of this module, you will work on a project to develop detailed EV models using Simscape and ADVISOR toolboxes. You will perform road load and aerodynamics analyses to optimize vehicle performance under varying environmental and operational conditions. 

Advanced Powertrain & Motor Control with MATLAB & ANSYS

• This module will teach you about EV powertrain systems, their key components, and their functions. This section takes you deeper into the hardware components of the EV powertrain, their management systems, and the standards, regulations, and best practices of the industry.
• The second section of this module teaches you how to model and simulate charging systems and motors within an EV powertrain. You will also go through the complete modeling and simulation of an EV powertrain.
• In the next section, you will explore static structural analysis to determine how materials and structures respond to constant loads. It also introduces you to modal analysis in ANSYS, helping you study vibration behavior in structures.
• The fourth section will guide you through thermal analysis using ANSYS to evaluate conduction, convection, and other heat transfer behaviors in various materials and systems. You will also be introduced to Computational Fluid Dynamics (CFD) in ANSYS, where you will simulate fluid flow and heat transfer in complex systems.
• Finally, in the last section, you will explore advanced nonlinear analysis techniques in ANSYS to model complex systems, helping you design for extreme conditions in automotive, aerospace, and structural engineering applications. You will also learn to use ANSYS for optimization and parametric studies to enhance design performance.
  
  
• Workshop Assignments: At the end of this section, you will be given three workshop assignments to practice and apply what you have learned.
  
  

• Project: You will work on a simulation-based project where you will validate EV components like chassis and battery enclosures using CFD for fluid flow analysis and FEA/FEM for structural and modal testing. 

Virtual Workshop: Embedded Development for EV Applications

At the end of the course, you will participate in a 14-day virtual workshop designed to help you gain practical, job-specific skills and become placement-ready. You will work on three hands-on projects, applying your knowledge from the EV course to real-world scenarios. This workshop contributes 450 marks to your final score.

1. Development of a Smart Battery Management System (BMS) Using STM32 Controllers:

In this workshop, you will design and develop a Smart BMS using STM32 controllers to manage battery health, charging cycles, and performance optimization for electric vehicles.

• Design and Implementation of an Embedded Charging Controller System for Electric Vehicles:

In this workshop, you will build a charging controller that ensures safe and efficient charging by optimizing power flow and circuit control in EVs.

• Real-Time CAN Communication Protocol Development for Multi-Controller EV Systems Using Embedded Systems:

In this workshop, you will develop a CAN communication protocol using embedded systems to enable seamless data exchange between multiple EV controllers.

Receive Exclusive Add-On with the Internshala’s Electric Vehicle Online Course

Enroll in this job-oriented course and receive an EV hardware kit worth ₹8000 for free! 

• Industry-Standard Tools: Learn to work on real-world applications with a customer-designed STM32 ARM Cortex system. 
• Project-Based Learning: Build functional systems from scratch with the help of 4 assignments and 6 EV-focused projects. 
• Simulation to Practical Use: Start with simulations and then move on to working with physical hardware in your complete training journey.
• Career-Enhancement Tool: Gain hands-on experience and become job-ready with the skills that top employers in the EV industry seek in potential candidates.

Explore Diverse Career Prospects After Pursuing Our Job-Oriented Electric Vehicle Course 

This job-oriented EV course helps both recent graduates and experienced professionals unlock various career opportunities. The skills you acquire in this course will help you land jobs in EV and engineering sectors, including:

• EV Systems Engineer: They design, develop, and test key systems in electric vehicles.
• Battery Technology Engineer: They work on improving battery performance and energy management in EVs.
• Power Electronics Engineer: They design and optimize power converters, inverters, and motor controllers for efficient energy flow.
• BMS (Battery Management Systems) Engineer: They develop systems to monitor and control battery health, safety, and performance.
• Simulation and Modeling Engineer: They create computer models to test and improve EV performance before real-world production.
• EV Design Engineer: They design the overall structure, components, and systems of an electric vehicle.

Enhance Your Skills with Offline Workshops

Gain exclusive access to Internshala’s EV course workshops and take your learning to the next level with hands-on experience. You will also get valuable insights from industry experts. Here’s what you can expect from the workshops:

• Choose Your Learning Mode: You get the flexibility to attend the workshops either offline or virtually, based on what suits your schedule and preferred learning style. No matter which mode you choose, you will receive the same high-quality learning materials and expert instruction.
• Learning with Projects: With 6 hands-on projects, you won’t just learn theory—you’ll apply it in real-world scenarios. These projects help solidify your knowledge and prepare you for the challenges you’ll face in the industry.

• Industry Expertise: You will learn from industry professionals who bring years of experience and real-world knowledge. Their guidance on electric vehicle topics—backed by mathematical and computational modeling—will keep you updated on the latest trends and technologies in the EV sector.
• In-depth Learning: These workshops will take you deep into electric vehicle technologies, covering both component-level details and system integration. Complex concepts are broken down thoroughly, helping you gain a comprehensive understanding of the EV field.

Why Should You Pursue Internshala’s Electric Vehicle Course?

Internshala’s job-oriented ev course is designed to help you build the skills needed for a successful career in the EV industry. Here’s why this course is a great choice for you:

• Comprehensive Curriculum: Learn everything from EV fundamentals like motors, batteries, and powertrains to advanced topics such as power electronics, embedded systems, and vehicle performance analysis.
• Hands-On Learning: Gain practical experience through MATLAB and ANSYS simulations, along with embedded systems programming to prepare you for real-world EV projects.
• Industry-Relevant Skills: Stay updated with the latest EV trends, including energy storage, motor control, and regulatory compliance, while also understanding the business and market aspects of the industry.
• Expert Mentor Support: Learn directly from industry professionals who provide valuable insights and guidance throughout the course.
• Plethora of Job Prospects: With in-depth knowledge of EV systems and engineering tools, you’ll be well-prepared for job opportunities in this rapidly growing sector.
• Flexible Learning: Study at your own pace with 100% online classes, making it easy to balance learning with your schedule.