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Academic Orientation Scheduled for 23rd November 2024

Future batches for this program will be announced in due course.

eMasters in Advanced Electrical Vehicle Systems

The eMasters in Advanced Electrical Vehicle Systems Systems is a specialized program designed for professionals in the electric vehicle (EV) industry. The online electric vehicle course covers a range of topics from basic electric and hybrid vehicle technologies to cutting-edge advancements in battery systems, propulsion methods, and sustainable energy. The curriculum ensures comprehensive knowledge of electric vehicle technology, including energy storage, powertrain engineering, and smart grid integration.

Duration:

Duration of the program will be 2 calendar years/ min. 4 semesters.

Maximum duration: 3 calendar years/ 6 semesters.


Eligibility:

Should be a working professional with at least two (2) years of experience.

Should have B.Tech/ BE/ M.Tech/ MSc (4 Semester Program)/ MCA (4 Semester Program)/ MS Degree (min. 4 Semester Program).

In the qualifying degree at least 55 percent marks or equivalent 5.5 CGPA/CPI must be there. In case of the candidate belonging to SC, ST, or Persons with Disability (PwD) category, this is relaxed to 50% or equivalent 5.0 CGPA/CPI. For MCA/MSC passed graduates, the percentage score of MCA/MSC would be considered. For BE/BTech Engineering graduates without PG specialization, the percentage score of the undergraduate degree would be considered. For a post graduation in the Engineering field of study, PG score qualification can be considered.

Selection process will be scheduled post counseling & application process, depending on the number of eligible applications as per seat availability for the program. This entire process will be online.

The applicants can be working professionals as well as non-working students with fresh degrees depending on the course.

Duration:
2 years

Program Fee:

3,35,000

(Excluding Optional Fee)
Download Brochure

Program Objectives

  • To introduce the fundamental concepts and technologies behind electric vehicles (EVs).
  • To analyze the challenges and future trends in the EV industry.
  • To gain proficiency in the use of control techniques for electric drives.
  • To provide an in-depth understanding of various battery technologies, including their chemistry, design, and applications.
  • To develop skills in analyzing, designing, and managing battery systems for various applications, including electric vehicles and renewable energy storage.
  • To develop skills in designing and evaluating renewable energy solutions for EV charging and power management.
  • To explore the design, operation, and optimization of power converters and control strategies for EV applications.
  • To evaluate the emerging trends and future developments in EV charging technologies and infrastructure.

Learning Outcomes

  • eMasters in Advanced Electrical Vehicle Systems program provides students with a comprehensive understanding of the principles and components of electric vehicles.
  • Ability to design and evaluate key components of electric vehicles, such as battery systems and electric motors.
  • Proficiency in analyzing the performance of various electric drive systems.
  • Capability to select appropriate drive systems for industrial applications.
  • Capability to apply knowledge of battery systems in real-world scenarios, particularly in electric vehicles and renewable energy solutions.
  • Knowledge of the impact of renewable energy integration on EV performance and sustainability.
  • Insight into emerging trends and technological advancements in renewable energy for electric vehicles.
  • Capability to utilize simulation tools for designing and testing power electronic systems in EV contexts.
  • Understanding of the integration of EV charging infrastructure with renewable energy sources.
  • Skills to analyze and predict the impact of EV charging technology on the energy sector.

Program Highlights

  • An esteemed certification, campus immersion & alumni status from IIT Bhilai
  • Learn through Virtual Instructor-Led Training (VILT)
  • Explore top-notch learning with industry experts

WHO IS THIS PROGRAM FOR?

  • Engineers and software developers seeking a profound understanding of advanced electric vehicle systems will discover this program to be invaluable for refining their expertise.
  • This program is also well-suited for entrepreneurs, innovators, and tech enthusiasts who are eager to master the intricacies of Advanced Electric Vehicle Systems.
  • The eMasters in Advanced Electrical Vehicle Systems Systems is designed to meet the needs of individuals who are enthusiastic about advancing their careers and making a significant impact in the digital age, particularly within the rapidly evolving landscape of electric mobility.
Course Structure:

Semester Course Code Course Name
I EVL501 Fundamentals of Electric Vehicles
I EVL504 Renewable Energy Systems for EVs
I EVL601 EV Charging Technology and Infrastructure
I EVL604 Energy Storage and Conversion
I EVL614 Environmental Impact of EVs
II EVL502 Electric Drives and Control
II EVL503 Battery Technology and Management Systems
II EVL602 Smart Grids and EV Integration
II EVL500 Basic Power Electronics for EVs
II EVL615 Thermal Management Systems in EV
II EVL606 Advanced Vehicle Dynamics
III EVP799 Minor Project
III EVL600 Advanced Power Electronics for EVs
III EVL617 Battery Manufacturing
III EVL603 High Voltage Systems in EVs
III EVL612 Project Management in EV Industry
III EVL613 EV Business Models and Market Analysis
IV EVP899 Major Project
IV EVL610 Autonomous and Connected Vehicles
IV EVL611 Sustainable Mobility Solutions
IV EVL607 Lightweight Materials for EVs
  • Core Courses: 12 Credits
  • Electives Courses: 12 Credits + 4 credits if Campus immersion program not chosen
  • Campus Immersion Program: 4 Credits (optional)
  • Project: 8 Credits
  • Total Credits: minimum 36 Credits
Elective Courses
Advanced Power Electronics for EVs Smart Grids and EV Integration
EV Charging Technology and Infrastructure High Voltage Systems in EVs
Energy Storage and Conversion Vehicle Aerodynamics
Advanced Vehicle Dynamics Lightweight Materials for EVs
Noise, Vibration, and Harshness (NVH) in EVs Suspension, Steering, and Braking Systems
Autonomous and Connected Vehicles Sustainable Mobility Solutions
Project Management in EV Industry EV Business Models and Market Analysis
- Environmental Impact of EVs
Module :
Fundamentals of Electric Vehicles
Module 1 - Introduction to Electric Vehicles
  1. History and Evolution of Electric Vehicles
  2. Types of Electric Vehicles: BEVs, HEVs, PHEVs
  3. Overview of Electric Vehicle Components
  4. Comparison of Electric and Conventional Vehicles
  5. Market Trends and Adoption of Electric Vehicles
  6. Regulatory Framework and Policies for Electric Vehicles
Module 2 - Electric Vehicle Powertrain and Components
  1. Electric Motors: Types, Operation, and Control
  2. Battery Technology: Types, Management Systems, and Charging
  3. Power Electronics: Converters and Inverters
  4. Transmission Systems in Electric Vehicles
  5. Thermal Management in Electric Vehicles
  6. Regenerative Braking Systems
Module 3 - Battery Technology and Management
  1. Types of Batteries Used in EVs
  2. Battery Chemistry and Cell Design
  3. Battery Management Systems (BMS)
  4. Charging Techniques and Infrastructure
  5. Battery Safety and Maintenance
  6. Battery Recycling and Second-Life Applications
Module 4 - Electric Vehicle Design and Dynamics
  1. Environmental Impact of Electric Vehicles
  2. Role of Electric Vehicles in Sustainable Mobility
  3. Integration with Renewable Energy Sources
  4. Smart Charging and Vehicle-to-Grid (V2G) Technologies
  5. Autonomous and Connected Electric Vehicles
  6. Future Trends and Challenges in the EV Sector
Module 5 - Sustainable Mobility and Future Trends
  1. "Electric Vehicle Technology Explained" by James Larminie and John Lowry
  2. "Modern Electric, Hybrid Electric, and Fuel Cell Vehicles" by Mehrdad Ehsani, Yimin Gao, and Stefano Longo
  3. "Electric and Hybrid Vehicles: Design Fundamentals" by Iqbal Husain
  4. "Advanced Electric Drive Vehicles" by Ali Emadi
Electric Drives and Control
Module 1 - Basics of Electric Drives
  1. Introduction to Electric Drives: Types and Applications
  2. Fundamentals of Electric Motors: DC, Induction, and Synchronous Motors
  3. Load Characteristics and Drive Ratings
  4. Power Electronic Converters in Electric Drives
  5. Motor Starting and Braking Methods
  6. Thermal Modeling and Cooling Techniques
Module 2 - Control of DC Drives
  1. Dynamics of DC Motors and Drive Systems
  2. Converter and Chopper Control of DC Drives
  3. Speed Control Methods for DC Motors
  4. Four Quadrant Operation and Regenerative Braking
  5. Closed-Loop Control Systems for DC Drives
  6. Applications of DC Drives in Industry
Module 3 - Control of AC Drives
  1. Principles of AC Motors: Induction and Synchronous
  2. Voltage and Frequency Control Methods
  3. Vector Control and Field-Oriented Control
  4. Sensor and Sensorless Control Techniques
  5. Soft Starters and Energy Efficiency
  6. Applications of AC Drives in Automation
Module 4 - Special Electric Drives
  1. Stepper Motor and Servo Drives
  2. Switched Reluctance Motors and Drives
  3. Permanent Magnet Motors and Drives
  4. Brushless DC Motors and Control
  5. Integrated Drive Systems and Smart Drives
  6. Emerging Trends in Electric Drives
Module 5 - Drive System Design and Applications
  1. Selection Criteria for Electric Drives
  2. Drive System Design Considerations
  3. Harmonics in Drive Systems and Mitigation Techniques
  4. Maintenance and Reliability of Drive Systems
  5. Case Studies in Industrial Applications
  6. Future Trends in Electric Drive Technology
Battery Technology and Management Systems
Module 1 - Battery Fundamentals
  1. Introduction to battery technology: history and evolution.
  2. Basic principles of electrochemistry relevant to batteries.
  3. Types of batteries: Lead-acid, Nickel-Cadmium, Lithium-ion, etc.
  4. Battery components and their functions: electrodes, electrolytes, separators.
  5. Battery specifications and performance metrics.
  6. Safety and environmental aspects of battery technology.
Module 2 - Lithium-Ion Batteries and Management
  1. Chemistry and design of lithium-ion batteries.
  2. Performance characteristics and applications of lithium-ion batteries.
  3. Battery management systems (BMS) for lithium-ion batteries.
  4. State of charge (SOC) and state of health (SOH) estimations.
  5. Thermal management in lithium-ion batteries.
  6. Aging mechanisms and lifespan considerations.
Module 3 - Advanced Battery Technologies
  1. Emerging battery technologies: Solid-state, Lithium-Sulfur, etc.
  2. Ultra-capacitors and hybrid energy storage systems.
  3. Innovations in battery design and materials.
  4. Flexible and wearable battery technologies.
  5. Energy density and power density trade-offs.
  6. Safety and reliability in advanced battery systems.
Module 4 - Battery Systems for Electric Vehicles
  1. Design considerations for EV battery packs.
  2. Charging strategies and infrastructure for electric vehicles.
  3. Battery swapping and fast-charging technologies.
  4. Battery economics and lifecycle analysis for EVs.
  5. Integration of battery systems in electric vehicle design.
  6. Case studies on EV battery management and performance.
Module 5 - Renewable Energy and Grid Storage
  1. Role of batteries in renewable energy systems.
  2. Grid-scale energy storage solutions.
  3. Integration of battery storage with solar and wind energy systems.
  4. Economics and policy frameworks for renewable energy storage.
  5. Battery recycling and second-life applications.
  6. Future trends and challenges in renewable energy storage.
Renewable Energy Systems for EVs
Module 1 - Basics of Renewable Energy for EVs
  1. Introduction to renewable energy sources and their application in EVs.
  2. Overview of solar, wind, hydro, and geothermal energy systems.
  3. Basics of photovoltaic (PV) systems and their integration in EV charging.
  4. Wind energy conversion systems suitable for EV applications.
  5. Hydro and geothermal energy potentials for EV charging infrastructure.
  6. Challenges and opportunities in renewable energy utilization for EVs.
Module 2 - Solar Energy Systems for EVs
  1. Principles of solar energy and photovoltaic technology.
  2. Design and implementation of solar-powered EV charging stations.
  3. Solar panel technologies and their efficiency in EV applications.
  4. Battery storage systems for solar-powered EV charging.
  5. Grid integration and net metering for solar EV charging stations.
  6. Case studies of solar energy use in EV infrastructure.
Module 3 - Wind and Hydro Energy for EVs
  1. Fundamentals of wind energy conversion for EVs.
  2. Design considerations for wind-powered EV charging stations.
  3. Hydroelectric power systems and their application in EV charging.
  4. Hybrid renewable energy systems (solar-wind-hydro) for EVs.
  5. Economic and environmental impact of wind and hydro energy in EVs.
  6. Real-world examples of wind and hydro-powered EV infrastructure.
Module 4 - Geothermal and Biomass Energy for EVs
  1. Introduction to geothermal energy and its application in EV charging.
  2. Biomass energy sources and conversion technologies for EVs.
  3. Design and challenges of geothermal and biomass-based EV stations.
  4. Environmental impacts and sustainability of geothermal and biomass energy.
  5. Integration of geothermal and biomass systems with EV infrastructure.
  6. Case studies and current developments in geothermal and biomass for EVs.
Module 5 - Emerging Trends and Future Perspectives
  1. Latest advancements in renewable energy technologies for EVs.
  2. Smart grid technologies and their role in renewable EV charging.
  3. Future prospects of renewable energy in electric vehicle industry.
  4. Policy, regulatory, and economic aspects of renewable energy for EVs.
  5. Innovations and research in renewable energy storage for EVs.
  6. Global case studies and success stories in renewable energy for EVs.
Advanced Power Electronics for EVs
Module 1 - Power Electronics in Electric Vehicles
  1. Overview of Power Electronics in EVs
  2. Types of Power Converters for EVs
  3. Design Principles of DC-DC Converters
  4. Role of AC-DC Converters in EV Charging
  5. Power Management Strategies in EVs
  6. Thermal Management in Power Electronic Systems
Module 2 - Motor Drives and Control
  1. Fundamentals of Electric Motors for EVs
  2. Power Electronic Converters for Motor Drives
  3. Control Techniques for Electric Motors
  4. Sensor and Sensorless Control of EV Motors
  5. Regenerative Braking Systems
  6. Case Studies of Motor Drives in EVs
Module 3 - EV Battery Management Systems
  1. Introduction to EV Battery Technologies
  2. Battery Management System (BMS) Architecture
  3. Power Electronics in BMS
  4. State of Charge (SoC) and State of Health (SoH) Estimation
  5. Battery Balancing Techniques
  6. Thermal Management in Battery Systems
Module 4 - EV Charging Systems and Infrastructure
  1. Overview of EV Charging Technologies
  2. On-board and Off-board Charging Systems
  3. Fast Charging Techniques and Standards
  4. Wireless Power Transfer Systems for EVs
  5. Grid Integration and Smart Charging
  6. Safety and Standards in EV Charging
Module 5 - Simulation and Modelling of EV Power Electronics
  1. Simulation Tools for Power Electronics
  2. Modelling of Converters and Motor Drives
  3. Simulation of Battery Management Systems
  4. Integration of Power Electronics in EV Powertrain Models
  5. Case Studies using Simulation Tools
  6. Future Trends in EV Power Electronics Simulation
EV Charging Technology and Infrastructure
Module 1 - Basics of EV Charging
  1. Overview of Electric Vehicles and Charging Basics
  2. Types of EV Chargers: Level 1, Level 2, and DC Fast Charging
  3. Electrical Fundamentals Relevant to EV Charging
  4. Standards and Protocols for EV Charging
  5. Safety Considerations in EV Charging
  6. User Interface and Experience in EV Charging Stations
Module 2 - EV Charging Infrastructure
  1. Planning and Designing EV Charging Stations
  2. Installation and Maintenance of Charging Stations
  3. Grid Integration and Load Management
  4. Payment Systems and Business Models for EV Charging
  5. Legal and Regulatory Framework for EV Charging Infrastructure
  6. Case Studies of Successful EV Charging Infrastructure Projects
Module 3 - Smart Charging and V2G Technology
  1. Introduction to Smart Charging and V2G (Vehicle-to-Grid)
  2. Communication Protocols and Network Connectivity
  3. Energy Management and Storage in EV Charging
  4. Impact of V2G on Grid Stability and Energy Efficiency
  5. Business Models and Economic Analysis of V2G
  6. Challenges and Solutions in Implementing V2G Technology
Module 4 - Renewable Energy Integration and Sustainability
  1. Solar-Powered EV Charging Stations
  2. Wind Energy and Other Renewable Sources for EV Charging
  3. Sustainability and Environmental Impact of EV Charging
  4. Lifecycle Analysis of EV Charging Infrastructure
  5. Policy and Incentives for Green EV Charging Solutions
  6. Future Trends in Renewable Energy Integration
Module 5 - Innovations and Future Trends in EV Charging
  1. Wireless EV Charging Technology
  2. Ultra-Fast Charging Developments
  3. Battery Swapping and Alternative Charging Technologies
  4. Artificial Intelligence and Machine Learning in EV Charging
  5. Impact of Autonomous Vehicles on EV Charging Infrastructure
  6. Future Scenarios and Potential Developments in EV Charging
Smart Grids and EV Integration
Module 1 - Introduction to Smart Grids
  1. Evolution of Electric Grids to Smart Grids
  2. Key Components of Smart Grids: Sensors, Smart Meters, and Communication Systems
  3. Benefits and Challenges of Smart Grids
  4. Energy Management in Smart Grids
  5. Regulatory and Policy Framework for Smart Grids
  6. Case Studies of Smart Grid Implementations Worldwide
Module 2 - Electric Vehicles and Their Impact on Grids
  1. Basics of Electric Vehicles: Types and Technologies
  2. EV Charging Technologies and Infrastructure
  3. Impact of EV Charging on Power Grids
  4. Demand Response and Load Management with EVs
  5. Vehicle-to-Grid (V2G) and Grid-to-Vehicle (G2V) Concepts
  6. Standards and Protocols for EV Integration
Module 3 - Renewable Energy and Smart Grid Integration
  1. Role of Renewable Energy in Smart Grids
  2. Integration of Solar and Wind Power in Smart Grids
  3. Energy Storage Systems in Smart Grids
  4. Smart Grids and Microgrids
  5. Challenges in Renewable Integration
  6. Case Studies of Renewable Energy in Smart Grids
Module 4 - Smart Grid Analytics and Technologies for EV Integration
  1. Data Analytics in Smart Grids
  2. IoT and AI Applications in Smart Grids
  3. Communication Technologies for Grid Management
  4. Smart Charging Technologies for EVs
  5. Grid Resilience and Security Aspects
  6. Future Trends in Smart Grid Technologies
Module 5 - Project Management and Case Studies in Smart Grids
  1. Project Planning and Management for Smart Grid Implementation
  2. Financial Modeling and Cost-Benefit Analysis
  3. Regulatory and Policy Implications
  4. Global Best Practices in Smart Grids and EV Integration
  5. Case Studies of EV Integration Projects
  6. Future Outlook and Research Directions in Smart Grids
High Voltage Systems in EVs
Module 1 - Fundamentals of High Voltage Systems in EVs
  1. Overview of Electric Vehicle Architecture
  2. High Voltage Batteries: Types, Characteristics, and Management
  3. Electric Motors and Inverters in EVs
  4. High Voltage Cabling and Connectors
  5. Safety Standards and Regulations for High Voltage Systems
  6. Thermal Management in High Voltage Systems
Module 2 - Design and Integration of High Voltage Systems
  1. Design Principles for High Voltage Components
  2. Integration of High Voltage Systems in EVs
  3. Power Distribution and Management
  4. High Voltage Charging Systems and Infrastructure
  5. Electromagnetic Compatibility (EMC) in EVs
  6. Cooling Systems for High Voltage Components
Module 3 - Maintenance and Diagnostics
  1. Preventive Maintenance for High Voltage Systems
  2. Diagnostic Tools and Techniques for High Voltage Components
  3. Fault Detection and Isolation Strategies
  4. Battery Health Monitoring and End-of-Life Scenarios
  5. Retrofitting and Upgrading High Voltage Systems
  6. Safety Procedures and Best Practices in Maintenance
Module 4 - Advanced Technologies and Innovations
  1. Next-Generation Battery Technologies
  2. Wireless Charging and Power Transfer
  3. Advanced Motor Control Techniques
  4. High Voltage Systems in Autonomous Vehicles
  5. Smart Grid Integration and Vehicle-to-Grid (V2G) Technologies
  6. Environmental Impact and Sustainability of High Voltage Systems
Module 5 - Case Studies and Practical Applications
  1. Case Study: Tesla's High Voltage System
  2. Case Study: High Voltage Systems in Commercial EVs
  3. Innovations in High Voltage Bus Systems
  4. Challenges and Solutions in EV Racing Applications
  5. Global Trends and Market Analysis
  6. Future Outlook and Emerging Opportunities
Energy Storage and Conversion
Module 1 - Fundamentals of Energy Storage
  1. Overview of Energy Storage Technologies
  2. Thermodynamics of Energy Storage
  3. Electrical Energy Storage Systems
  4. Thermal Energy Storage Methods
  5. Mechanical Energy Storage Techniques
  6. Chemical Energy Storage and Hydrogen Energy Systems
Module 2 - Battery Technologies
  1. Principles of Battery Operation
  2. Types of Batteries: Lead-Acid, Lithium-Ion, and Others
  3. Battery Management Systems
  4. Battery Performance Metrics
  5. Environmental Impact of Batteries
  6. Future Trends in Battery Technology
Module 3 - Renewable Energy Conversion
  1. Solar Energy Conversion: Photovoltaics
  2. Wind Energy Conversion Systems
  3. Hydro and Tidal Energy Conversion
  4. Biomass to Energy Conversion Technologies
  5. Geothermal Energy Utilization
  6. Integration of Renewable Energy Sources
Module 4 - Grid Integration and Energy Management
  1. Smart Grid Concepts and Technologies
  2. Energy Storage in Grid Applications
  3. Demand Response and Load Management
  4. Energy Storage for Electric Vehicles
  5. Microgrids and Distributed Energy Resources
  6. Regulatory and Policy Framework for Energy Storage
Module 5 - Advanced Topics in Energy Storage and Conversion
  1. Emerging Technologies in Energy Storage
  2. Nanotechnology in Energy Storage and Conversion
  3. Energy Harvesting Techniques
  4. Thermal-to-Electrical Energy Conversion
  5. Fuel Cells and Hydrogen Economy
  6. Life Cycle Analysis of Energy Systems
Vehicle Aerodynamics
Module 1 - Introduction to Vehicle Aerodynamics
  1. Basics of fluid mechanics and airflow around vehicles.
  2. Aerodynamic forces and moments: Drag, lift, and side forces.
  3. The concept of aerodynamic drag and its impact on vehicle performance.
  4. Introduction to boundary layers and their role in vehicle aerodynamics.
  5. Vehicle shapes and their aerodynamic characteristics.
  6. Overview of wind tunnel testing and CFD in vehicle aerodynamics.
Module 2 - Aerodynamics of Passenger Cars
  1. Aerodynamic design considerations for passenger cars.
  2. Effects of body shape, size, and add-ons on aerodynamics.
  3. Analysis of airflow patterns around sedans, hatchbacks, and SUVs.
  4. Case studies of aerodynamic optimization in passenger cars.
  5. Role of aerodynamics in vehicle noise reduction.
  6. Emerging trends in passenger car aerodynamics.
Module 3 - Aerodynamics of Commercial Vehicles
  1. Unique aerodynamic challenges for trucks, buses, and trailers.
  2. Design strategies for reducing drag in commercial vehicles.
  3. Influence of crosswinds and vehicle stability.
  4. Aerodynamic devices for commercial vehicles (spoilers, vortex generators).
  5. Case studies of aerodynamic improvements in commercial vehicles.
  6. Regulatory and environmental considerations.
Module 4 - Advanced Topics in Vehicle Aerodynamics
  1. Ground effect and its implications in vehicle design.
  2. Aerodynamics of high-performance and racing cars.
  3. Impact of aerodynamics on electric and hybrid vehicles.
  4. Active aerodynamics: Adaptive and smart aerodynamic systems.
  5. Computational techniques in aerodynamic design and analysis.
  6. Future trends and innovations in vehicle aerodynamics.
Module 5 - Practical Applications and Case Studies
  1. Hands-on experience with CFD software for vehicle aerodynamics.
  2. Wind tunnel testing: Methodology and data interpretation.
  3. Case studies of aerodynamic design in real-world vehicles.
  4. Project work: Designing a vehicle component with improved aerodynamics.
  5. Industry best practices and standards in aerodynamic testing.
  6. Discussion on the role of aerodynamics in sustainable vehicle design.
Advanced Vehicle Dynamics
Module 1 - Vehicle Dynamics Fundamentals
  1. Introduction to Vehicle Dynamics: Basic Concepts and Terminology
  2. Tire Mechanics: Forces and Moments
  3. Longitudinal Dynamics: Acceleration and Braking
  4. Lateral Dynamics: Cornering and Steering
  5. Vertical Dynamics: Ride Comfort and Road Handling
  6. Vehicle Stability and Control Systems Overview
Module 2 - Advanced Tire Modeling
  1. Tire Modeling Techniques and Theories
  2. Tire-Road Interaction and Friction Models
  3. Thermal Effects in Tire Dynamics
  4. Experimental Methods in Tire Data Analysis
  5. Tire Dynamics in Vehicle Simulation
  6. Influence of Tire Characteristics on Vehicle Performance
Module 3 - Aerodynamics and Vehicle Performance
  • Basics of Aerodynamics in Vehicle Design
  • Aerodynamic Forces and Their Effects on Vehicle Dynamics
  • Aerodynamic Optimization Techniques
  • Wind Tunnel Testing and Computational Fluid Dynamics (CFD)
  • Influence of Aerodynamics on Fuel Efficiency and Performance
  • Case Studies: Aerodynamic Design in Motorsports
    • Module 4 - Suspension and Steering Systems
    1. Design Principles of Suspension Systems
    2. Types of Suspension Systems and Their Dynamics
    3. Steering System Mechanics and Control
    4. Advanced Concepts in Active Suspension and Steering
    5. Analysis of Suspension and Steering System Performance
    6. Case Studies: Suspension and Steering Systems in High-Performance Vehicles
    Module 5 - Vehicle Dynamics Control and Simulation
    1. Vehicle Dynamics Control Systems: ABS, TCS, ESC
    2. Advanced Control Strategies for Vehicle Stability
    3. Modeling and Simulation Tools in Vehicle Dynamics
    4. Real-Time Simulation and Hardware-in-the-Loop (HIL) Testing
    5. Case Studies: Control System Design in Automotive Engineering
    6. Future Trends in Vehicle Dynamics Simulation and Control
Lightweight Materials for EVs
Module 1 - Introduction to Lightweight Materials for EVs
  1. Overview of Electric Vehicles and the Importance of Lightweighting
  2. Types of Lightweight Materials: Metals, Alloys, Composites, and Plastics
  3. Properties of Lightweight Materials: Strength, Durability, and Weight
  4. Application Areas in EVs: Body, Chassis, Battery, and Interior Components
  5. Benefits of Lightweight Materials in EV Performance and Range
  6. Challenges in Material Selection for EVs
Module 2 - Metals and Alloys in EVs
  1. Aluminum and Aluminum Alloys: Properties and Applications
  2. Magnesium Alloys: Characteristics and Use in EVs
  3. High Strength Steel: Advantages and Implementation in EV Structure
  4. Titanium in EVs: Uses and Material Properties
  5. Manufacturing Processes for Metals and Alloys in EVs
  6. Case Studies: Successful Implementation in Current EV Models
Module 3 - Composite Materials in EVs
  1. Introduction to Composite Materials: Fibers and Matrices
  2. Carbon Fiber Reinforced Plastics (CFRP): Properties and Applications
  3. Glass Fiber Reinforced Plastics (GFRP): Use in EVs
  4. Manufacturing Techniques for Composite Materials in EVs
  5. Advantages and Challenges of Composites in Vehicle Lightweighting
  6. Recent Developments and Innovations in Composite Materials for EVs
Module 4 - Plastics and Other Materials in EVs
  1. Role of Plastics in EV Lightweighting
  2. High-Performance Plastics: Types and Applications in EVs
  3. Thermoplastics and Thermosetting Plastics: Characteristics and Uses
  4. Bio-based and Recycled Materials in EVs: Opportunities and Challenges
  5. Lightweighting with Foam Materials and Honeycomb Structures
  6. Future Trends in Plastic Materials for EVs
Module 5 - Sustainability and Future Trends
  1. Environmental Impact of Lightweight Materials in EVs
  2. Recycling and Lifecycle Analysis of EV Materials
  3. Innovative Materials and Technologies in Development for EVs
  4. Role of Nanotechnology in EV Material Advancements
  5. Regulatory Framework and Safety Standards for EV Materials
  6. Future Outlook: Lightweighting and Its Impact on EV Industry
Noise, Vibration, and Harshness (NVH) in EVs
Module 1 - Fundamentals of NVH in EVs
  1. Introduction to NVH: Definitions, Importance, and Challenges in EVs
  2. Sources of Noise and Vibration in Electric Vehicles
  3. Basics of Acoustics and Vibration Theory
  4. Comparison of NVH in EVs vs. Internal Combustion Engine Vehicles
  5. Instrumentation and Measurement Techniques for NVH
  6. Human Perception and Tolerance to NVH
Module 2 - NVH Analysis and Measurement in EVs
  1. NVH Testing Methodologies and Equipment
  2. Data Acquisition and Signal Processing for NVH Analysis
  3. Psychoacoustic Metrics in NVH Analysis
  4. Case Studies: NVH Analysis in Different EV Models
  5. Road and Chassis Dynamics Influencing NVH
  6. Aerodynamic Noise in Electric Vehicles
Module 3 - NVH Control and Reduction Techniques
  1. Materials and Design for Noise Absorption and Isolation
  2. Active Noise Control and Vibration Damping Technologies
  3. Electric Motor and Powertrain NVH Mitigation Strategies
  4. Vehicle Body and Chassis Modifications for NVH Reduction
  5. Sound Quality Engineering in EVs
  6. Role of Software and Simulation in NVH Control
Module 4 - Regulatory and Industry Standards for NVH in EVs
  1. Global NVH Standards and Regulations for Electric Vehicles
  2. Customer Expectations and Market Trends in EV NVH
  3. OEM Strategies for NVH Compliance
  4. NVH in Autonomous and Connected EVs
  5. Safety Considerations and NVH
  6. Future Developments in NVH Standards for EVs
Module 5 - Case Studies and Practical Applications
  1. Comparative NVH Study of Leading EV Models
  2. NVH Challenges and Solutions in High-Performance EVs
  3. Impact of NVH on EV Battery Efficiency and Range
  4. Retrofitting NVH Solutions in Existing EV Models
  5. Industry Best Practices in NVH Management for EVs
  6. Emerging Technologies and Innovations in EV NVH
Suspension, Steering, and Braking Systems
Module 1 - Suspension Systems
  1. Overview of Suspension Systems: Types and Functions
  2. Springs and Dampers: Design and Material Considerations
  3. Suspension Geometry: Camber, Caster, and Toe
  4. Independent and Dependent Suspension Systems
  5. Load Distribution and Suspension Tuning
  6. Advanced Technologies in Suspension Systems
Module 2 - Steering Systems
  1. Fundamentals of Steering Systems
  2. Types of Steering Mechanisms: Rack-and-Pinion, Recirculating Ball
  3. Power Steering: Hydraulic vs Electric Systems
  4. Steering Geometry and Alignment
  5. Steering System Maintenance and Troubleshooting
  6. Innovations in Steering Technology
Module 3 - Braking Systems
  1. Principles of Vehicle Braking
  2. Disc and Drum Brakes: Components and Functioning
  3. Anti-lock Braking System (ABS) and Electronic Stability Control (ESC)
  4. Brake Force Distribution and Brake-by-Wire Technology
  5. Maintenance and Troubleshooting of Braking Systems
  6. Future Trends in Braking Technologies
Module 4 - Integration of Systems
  1. Interaction Between Suspension, Steering, and Braking
  2. Vehicle Dynamics and Handling
  3. Safety Considerations in System Design
  4. Performance Tuning and Enhancement Techniques
  5. Case Studies of System Integration in Modern Vehicles
  6. Simulation and Testing of Integrated Systems
Module 5 - Advanced Topics and Emerging Technologies
  1. Adaptive Suspension and Steering Systems
  2. Regenerative Braking Systems
  3. Autonomous Vehicle Steering and Braking Technologies
  4. Impact of Electric Vehicles on System Design
  5. Innovations in Materials and Manufacturing
  6. Future Directions in Vehicle Systems Technology
Autonomous and Connected Vehicles
Module 1 - Introduction to Autonomous Vehicles
  1. History and Evolution of Autonomous Vehicles
  2. Key Technologies in Autonomous Vehicles (Sensors, AI, Machine Learning)
  3. Levels of Vehicle Autonomy
  4. System Design and Architecture for Autonomous Vehicles
  5. Safety and Reliability in Autonomous Vehicles
  6. Current Challenges and Future Trends
Module 2 - Connected Vehicle Technologies
  1. Basics of Vehicle-to-Vehicle (V2V) and Vehicle-to-Infrastructure (V2I) Communication
  2. Standards and Protocols for Connected Vehicles
  3. Data Security and Privacy in Connected Vehicles
  4. Impact of Connectivity on Traffic Management and Control
  5. Smart Transportation and Urban Mobility
  6. Integration of Connected Vehicles with Smart Cities
Module 3 - Sensor and Perception Technologies
  1. Overview of Sensors in Autonomous Vehicles (RADAR, LIDAR, Cameras)
  2. Data Fusion and Sensor Integration
  3. Object Detection and Classification
  4. Environmental Perception and Mapping
  5. Advanced Driver-Assistance Systems (ADAS)
  6. Challenges in Perception under Various Conditions
Module 4 - Autonomous Vehicle Control and Decision Making
  1. Path Planning and Navigation
  2. Control Algorithms for Autonomous Driving
  3. Real-time Decision Making in Autonomous Vehicles
  4. Interaction with Non-autonomous Traffic
  5. Simulation and Testing of Autonomous Vehicle Systems
  6. Ethical Decision Making in Autonomous Vehicles
Module 5 - Legal, Ethical, and Social Aspects
  1. Regulatory Framework for Autonomous and Connected Vehicles
  2. Ethical Considerations and Accountability
  3. Impact on Employment and Society
  4. User Acceptance and Behavioral Aspects
  5. Privacy Issues and Data Governance
  6. Future of Mobility and Societal Transformations
Sustainable Mobility Solutions
Module 1 - Fundamentals of Sustainable Mobility
  1. Definition and Importance of Sustainable Mobility
  2. Historical Evolution of Transportation Systems
  3. Environmental Impact of Transportation
  4. Social and Economic Aspects of Mobility
  5. Urban Planning and Transportation
  6. Policy Frameworks for Sustainable Mobility
Module 2 - Technologies in Sustainable Transportation
  1. Electric Vehicles and Charging Infrastructure
  2. Alternative Fuels and Energy Sources
  3. Intelligent Transportation Systems (ITS)
  4. Public Transportation Systems and Management
  5. Non-Motorized Transportation (Cycling, Walking)
  6. Innovation in Transportation Technology
Module 3 - Policy and Planning for Sustainable Mobility
  1. Urban Transportation Planning and Management
  2. Traffic Demand Management Strategies
  3. Land Use and Transportation Integration
  4. Global and National Transportation Policies
  5. Public Participation in Transportation Planning
  6. Case Studies of Sustainable Mobility Initiatives
Module 4 - Sustainable Transportation Design and Implementation
  1. Design Principles for Sustainable Transportation Systems
  2. Sustainable Roadway Design and Traffic Calming Measures
  3. Public Transit System Design and Optimization
  4. Pedestrian and Bicycle-Friendly Infrastructure
  5. Environmental Impact Assessment (EIA) for Transportation Projects
  6. Implementation Strategies and Challenges
Module 5 - Future Trends and Innovations in Sustainable Mobility
  1. Smart Cities and Mobility
  2. Autonomous and Connected Vehicles
  3. Mobility as a Service (MaaS)
  4. Climate Change and Transportation Resilience
  5. International Best Practices in Sustainable Mobility
  6. Future Challenges and Opportunities in Sustainable Transportation
Project Management in EV Industry
Module 1 - Introduction to EV Industry and Project Management
  1. Overview of the EV industry: History, current trends, and future outlook.
  2. Basic principles of project management: Scope, time, cost, quality, human resource, communication, risk, procurement, and stakeholder management.
  3. Project life cycle and phases in the context of EV projects.
  4. Role of sustainability and innovation in EV project management.
  5. Introduction to project management tools and software relevant to the EV industry.
  6. Case studies of successful and failed EV projects.
Module 2 - Project Planning and Execution in EV Industry
  1. Project charter and scope definition for EV projects.
  2. Time management: Scheduling techniques and tools.
  3. Cost estimation and budgeting for EV projects.
  4. Quality management in EV projects: Standards and practices.
  5. Resource management: Human, material, and technological resources.
  6. Execution strategies for EV projects: Agile, Waterfall, and Hybrid approaches.
Module 3 - Risk Management and Decision Making in EV Projects
  1. Risk identification and analysis in EV projects.
  2. Strategies for risk mitigation and management.
  3. Decision-making processes in the face of uncertainties.
  4. Impact of regulatory and environmental factors on EV projects.
  5. Stakeholder analysis and management in EV projects.
  6. Crisis management and contingency planning in EV projects.
Module 4 - Leadership and Communication in EV Project Management
  1. Leadership styles and their impact on project success.
  2. Team building and motivation in a project environment.
  3. Effective communication strategies within project teams and with external stakeholders.
  4. Conflict resolution and negotiation skills in project management.
  5. Cultural and ethical considerations in global EV projects.
  6. Change management in EV projects.
Module 5 - Emerging Trends and Future of EV Project Management
  1. Technological advancements impacting the EV industry.
  2. Project management in the context of electric autonomous vehicles.
  3. Integration of renewable energy sources in EV projects.
  4. Future challenges and opportunities in EV project management.
  5. Case studies on innovative EV projects.
  6. Future skills and competencies required in EV project management.
EV Business Models and Market Analysis
Module 1 - Introduction to EV Market and Business Models
  1. Overview of the Electric Vehicle (EV) Industry
  2. Key Players in the EV Market: Manufacturers, Service Providers, and Consumers
  3. Traditional vs. Innovative Business Models in EV
  4. Revenue Streams in the EV Industry: Direct Sales, Leasing, and Ancillary Services
  5. Case Studies of Successful EV Business Models
  6. Emerging Trends and Future Outlook
Module 2 - Market Analysis Techniques and Tools
  1. Fundamentals of Market Analysis: Demand, Supply, and Price Dynamics
  2. Tools for Market Analysis: SWOT, PESTEL, and Porter’s Five Forces
  3. Consumer Behavior and Segmentation in the EV Market
  4. Competitive Analysis and Benchmarking
  5. Forecasting Models for EV Demand and Supply
  6. Evaluating Market Entry and Expansion Strategies
Module 3 - Regulatory Frameworks and Policy Impacts
  1. Overview of Global EV Policies and Regulations
  2. Impact of Government Incentives and Subsidies on EV Adoption
  3. Regulatory Challenges and Barriers in EV Market Entry
  4. Case Studies of Policy-Driven EV Market Transformations
  5. Compliance and Standards in the EV Industry
  6. Future Policy Trends and Their Implications
Module 4 - Technology and Innovation in EV Business Models
  1. Role of Technology in Shaping EV Business Models
  2. Analysis of EV Technology Trends: Batteries, Charging Infrastructure, etc.
  3. Innovation in EV Services: Car Sharing, Battery Swapping, etc.
  4. Impact of Digital Transformation on the EV Industry
  5. Collaborations and Partnerships in EV Technology Development
  6. Case Studies of Technology-Driven EV Business Models
Module 5 - Strategic Planning and Decision Making in EV Business
  1. Strategic Management Principles in the EV Industry
  2. Tools and Techniques for Strategic Decision Making
  3. Risk Management and Mitigation in EV Business Models
  4. Building Sustainable and Scalable EV Business Strategies
  5. Leadership and Change Management in EV Organizations
  6. Preparing for Future Challenges and Opportunities in the EV Market
Environmental Impact of EVs
Module 1 - EV Production and Raw Material Extraction
  1. Overview of EV manufacturing process
  2. Environmental impact of battery raw material extraction (e.g., lithium, cobalt)
  3. Life cycle assessment methodologies for EVs
  4. Comparison of EV production emissions with conventional vehicles
  5. Role of supply chain management in minimizing environmental impact
  6. Strategies for sustainable raw material sourcing
Module 2 - Emissions During Operation and Charging Infrastructure
  1. Analysis of direct and indirect emissions from EVs
  2. Impact of electricity generation mix on EV emissions
  3. Design and deployment of sustainable EV charging infrastructure
  4. The role of smart charging in reducing grid impact
  5. Comparison of EV emissions in different geographical regions
  6. Future trends in low-emission electricity for EV charging
Module 3 - Battery Life Cycle and Recycling
  1. Battery technology and lifespan in EVs
  2. Environmental implications of battery disposal
  3. Advances in battery recycling technologies
  4. Policies and regulations for EV battery lifecycle management
  5. Case studies in battery reuse and repurposing (e.g., energy storage)
  6. Challenges and opportunities in end-of-life battery management
Module 4 - Policy, Regulation, and Market Dynamics
  1. Overview of global EV policies and their environmental implications
  2. Incentives and subsidies for EV adoption and their impact
  3. Regulatory challenges for EV integration into the transport sector
  4. Market dynamics and consumer behavior influencing EV adoption
  5. Comparative study of EV policies in different countries
  6. Future policy trends and their potential environmental impact
Module 5 - EVs and Renewable Energy Integration
  1. Role of EVs in enhancing renewable energy adoption
  2. Impact of EVs on electricity grid stability and demand management
  3. Synergies between EV charging and renewable energy sources
  4. Technological advancements in V2G (Vehicle-to-Grid) systems
  5. Case studies of successful EV-renewable energy integration
  6. Challenges and solutions for large-scale EV and renewable energy integration
Program Fee :

eMasters in Advanced Electrical Vehicle Systems Sem 1 Sem 2 Sem 3 Sem 4
Application Fee (Non Refundable ) 5,000 - - -
Admission Fee (Including Workshop /Training) 82,500 82,500 82,500 82,500
Instalment 1 42,500 - - -
Instalment 2 40,000 - - -
Optional Campus Immersion Fee - 10,000 - 10,000
Optional Institute Alumni Fee - - - 6,000
Total Fee (Excluding Optional Fee) 3,35,000

Refund Policy:

Click Here to check the refund policy

  • Application/Registration fees is non-refundable.
  • Fees will be collected only after IIT Bhilai confirms the batch start date.
  • 90% refund of the paid Course fee is applicable if requested on or before 30 days of the batch commencement date.
  • No refund is applicable post- batch commencement.

Program Certificate


Executive M.Tech in Data Science & Data Analytics

eMasters in Advanced Electrical Vehicle Systems

Complete the program successfully to obtain this valuable certificate.

Admission Process


Selection process will be scheduled post-counseling & application process, depending on the number of eligible applications
as per seat availability for the program. This entire process will be online.

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