- Program Highlights
The Advanced Certification Program in Embedded Systems for Electric Vehicle Engineering is an intensive 3-month program designed to provide participants with in-depth knowledge and hands-on experience in embedded systems tailored for electric vehicle (EV) applications. Covering topics from EV engineering essentials to advanced ARM Cortex development, the program prepares engineers to design, program, and integrate embedded systems critical for EV functionality and performance
Leverage the prestige of IIT Guwahati
- Admission Closes on 1st Nov
Days
Hours
Minutes
Seconds
- Get more information
Want to know more? Enter your information to learn more about this program from EICT – IIT Guwahati.
- Career Opportunities
- Embedded systems design and programming for EVs: Developing and coding embedded systems for efficient EV operations.
- Power electronics development and simulation: Designing and simulating power management systems for EVs.
- Microcontroller-based system integration: Implementing microcontroller-driven solutions for EV components.
- Real-time operating systems for EV applications: Creating RTOS-based systems for real-time EV functionality.
- Converter design for embedded systems: Designing efficient converters for embedded power applications in EVs.
- Motor control systems in EV Powertrains: Engineering precise motor control solutions for EV propulsion.
- Communication protocol implementation in EVs: Integrating CAN, LIN, or other protocols for seamless EV communication.
- Circuit design and debugging for embedded systems: Creating and troubleshooting circuits for embedded EV applications.
- ARM Cortex-based system development: Developing ARM Cortex-based systems for advanced EV solutions.
- Sensor interfacing and integration in EVs: Connecting and calibrating sensors for optimal EV performance.
- Embedded Systems Engineer: Designs and develops embedded systems for EV applications.
- ARM Cortex Developer: Specializes in programming and optimizing ARM Cortex processors for EV systems.
- Microcontroller Programmer for EVs: Codes and integrates microcontroller solutions tailored to EV technology.
- Power Electronics Engineer: Develops and tests power conversion and management systems for EVs.
- Circuit Design Specialist: Designs and validates circuits for embedded EV systems.
- Motor Control Developer: Engineers advanced motor control systems for EV Powertrains.
- Embedded Systems Integrator: Integrates and optimizes embedded hardware and software in EVs.
- Real-Time Systems Developer: Builds real-time systems for critical EV applications.
- Arduino and STM32 Programmer: Programs Arduino and STM32 platforms for EV prototyping and development.
- EV System Architect: Designs and oversees the integration of EV system components.
- Proficiency in Embedded C and Microcontroller Programming: Skilled in writing efficient code for Microcontroller-based systems.
- Expertise in circuit simulation using Proteus: Capable of designing and testing circuits virtually with Proteus software.
- Knowledge of STM32 and ARM Cortex-M processors: In-depth understanding of programming and applications for these processors.
- Familiarity with ADCs, timers, and interrupts in embedded systems: Skilled in configuring and utilizing core microcontroller features.
- Sensor interfacing and peripheral integration: Proficient in connecting and managing sensors and peripherals in systems.
- Debugging and testing embedded systems: Experienced in diagnosing and resolving issues in embedded hardware and software.
- Communication protocol implementation (I2C, SPI, UART): Adept at setting up and troubleshooting data communication between devices.
- Real-time operating system development: Competent in creating systems with real-time response capabilities.
- Converter design and motor control programming: Skilled in developing power converters and control algorithms for motors.
- Problem-solving in EV-specific embedded applications: Ability to address technical challenges in EV embedded systems.
- Tata Motors
- Bosch India
- Hero Electric
- Mahindra Electric
- Ola Electric
- Ather Energy
- Ashok Leyland
- Continental Automotive
- Hyundai Motor India
- L&T Technology Services
- Exicom Power Solutions
- Wipro Automotive
- TVS Motor Company
- KPIT Technologies
- Siemens India
- FOR ENTERPRISE
Looking to enroll your employees into this program ?
- Inquire Now
- Program Outcomes
- Program Curriculum
Module 1: EV Engineering Essentials Part I and II
- Module Description:
- This foundational module introduces the fundamentals of EV technology, covering components, key technologies, and the transition from internal combustion engines (ICE) to EVs. Topics include EV design principles, battery technology, power electronics, motor systems, and electrification systems. The module also explores EV charging technologies, including CCS, CHAdeMO, and fast charging solutions.
- Module Details:
- Starting with EV Technology: Overview of Electric Vehicles, Components, Key Technologies
- Understanding ICE to EV Transition: Key Differences, Benefits, Challenges
- Electric Vehicle Engineering: EV Design Principles, Key Subsystems, Safety Considerations
- Battery Technology for EV Systems: Battery Chemistries, Energy Density, Charging Cycles
- Power Electronics for EV Systems: Inverters, Converters, Power Management
- Motor Systems for Electric Vehicles: Types of Motors, Control Strategies, Efficiency Optimization
- Vehicle Electrification Systems: Vehicle Wiring, Voltage Distribution, High and Low Voltage Components
- Electric Vehicle Charging Technology: Charging Infrastructure, Standards (CCS, CHAdeMO), Fast Charging Solutions
Module 2: Power Electronics and Circuit Design for Electric Vehicles: Analog, Digital, and Proteus Simulation Techniques
- Module Description:
- Participants learn the principles of semiconductor electronics, covering diodes, rectifiers, filters, and specialized circuits like voltage doublers and operational amplifiers. The module also introduces BJT, FET, MOSFET, and IGBT devices, along with Boolean algebra and logic gate systems. Students gain hands-on experience with Proteus-based circuit designing, enabling them to create and simulate complex electronic circuits.
- Module Details:
- Introduction to Semiconductor Electronics
- Semiconductor and Diode Configuration
- Rectifiers and Filters in Electronics Systems
- Clippers in Electronic Systems
- Clamper & Voltage Doubler Circuits
- Special Purpose Diodes
- BJT and FET Devices
- MOSFET and IGBT Devices
- Amplifier Circuits (Operational & Differential)
- Number Systems and Conversions
- Boolean algebra and logic gate systems
- Proteus based Circuit Designing
Module 3: Essentials of Embedded Systems for Electric Vehicles: Embedded C, Microcontrollers, Arduino, and Simulation
- Module Description:
- This module focuses on embedded systems and their critical role in EVs. Topics include programming with Embedded C, microcontroller architecture (8051), Arduino-based systems, and embedded simulations using Proteus. Participants also explore STM Cube IDE for programming STM32 microcontrollers and ARM Cortex-M processors, integrating sensors, peripherals, and communication protocols.
- Module Details:
- Introduction: Overview of Embedded Systems in EVs, Role of Embedded Systems in Electric Vehicles
- Embedded Systems with 8051 Microcontroller: Architecture, Basic Interfacing, Programming
- Embedded C language Programming: Syntax, Control Flow, Embedded Libraries
- Embedded with Arduino: Hardware, Software, Sensor Interfacing, Communication Protocols
- Embedded Simulations using Proteus: Circuit Simulation, Debugging Techniques
- Embedded STM Cube IDE: Programming STM32 Microcontrollers, Development Tools
- Embedded ARM Cortex Systems: ARM Cortex-M Processors, Programming, Peripherals Integration
Module 4: Embedded System Design Using ARM Cortex Controller System
- Module Description:
- This advanced module delves into ARM Cortex systems, focusing on STM32 microcontroller architecture and programming. Topics include ADCs, timers, interrupts, and communication protocols. Participants learn to design and develop converters, work with real-time operating systems, and integrate timers and motors with STM32 for EV-specific applications.
- Module Details:
- Introduction to microcontrollers
- Getting started with STM32
- STM32 Architecture
- Basic programming with STM-32
- Analog to Digital Conversion
- Working with Timers and Interrupts
- Communication Protocols
- Real Time Operating System
- Converter Design and development with STM32
- Timers & motors with STM32
- Skills Covered
Proficiency in Embedded C and Microcontroller Programming
Expertise in Circuit simulation Using Proteus
Knowledge of STM32 and ARM Cortex-M Processors
Familiarity with ADCs, timers, and interrupts in embedded systems
Sensor interfacing and peripheral integration
Debugging and testing embedded systems
Communication protocol implementation (I2C, SPI, UART)
Real-time operating system development
Converter design and motor control programming
Problem-solving in EV-specific embedded applications
- Projects
Advanced Sensor Systems with Arduino
Design and implement sensor-based systems using Arduino to capture, process, and display real-time data for embedded applications.
Embedded Battery Monitoring System Development
Build a communication system utilizing CAN bus and PWM signals for reliable data exchange in electric vehicle components.
CAN Bus and PWM Communication System for EV
Build a communication system utilizing CAN bus and PWM signals for reliable data exchange in electric vehicle components.
Development of Battery Overcurrent Protection
Detect and respond to overcurrent situations in a simulated battery system.
- Benefits
- Learn foundational and advanced embedded systems concepts.
- Hands-on exposure to STM32 and Arduino programming.
- Develop practical skills in circuit design and simulation.
- Prepare for in-demand jobs in the EV industry.
- Build a portfolio with real-world projects and workshop experience.
- Enhance expertise in embedded systems and microcontroller.
- Gain hands-on experience with real-world EV applications.
- Expand career opportunities in the EV and automotive industry.
- Learn advanced ARM Cortex development techniques.
- Build industry-relevant projects for a strong portfolio.
- Design and program embedded systems for EV applications.
- Develop and simulate circuits using Proteus.
- Program microcontrollers (STM32, Arduino) for EV-specific tasks.
- Implement communication protocols in embedded systems.
- Debug and test embedded systems for real-world applications.
- Integrate sensors and peripherals into EV systems.
- Build real-time systems for efficient EV operation.
- Mode of Learning
Complete on-site
classroom program
Location: Mumbai
LIVE + Recorded + Onsite + Hardware + Workshop
LIVE + Weekend on-site sessions
Location: Pune, Delhi
LIVE + Recorded + Hardware + Workshop
Location: Global
- Tools Covered
Hardware Labs Access
Two-Wheeler Simulator & Test Bench
The 2 Wheeler Simulator & Testbench focuses on evaluating EV battery performance, including voltage, current, discharge profiles, and capacity testing under various load conditions. It also covers Battery Management System (BMS) testing and dynamic load analysis to optimize electric bike performance and safety.
LAB 1
Charging Station Simulator and Test Bench
The Charging Station Simulator and Test Bench covers experiments focusing on the efficiency, behavior, and safety features of EV charging systems. It includes the measurement of voltage, current, and power consumption during charging, and tests security features like RFID and OTP-based authentication. Key areas include energy efficiency analysis, protection unit testing, and charging behavior under different conditions
LAB 2
EV In-house manufacturing & Development KIT
The EV In-house Manufacturing & Development KIT provides all the essential tools and components for building and prototyping electric vehicles, supporting the entire development process from concept to production. It includes equipment for battery monitoring, motor control, system integration, and real-time data analysis, ensuring seamless development for EV projects
LAB 5
