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M-TECH in Power Electronics And Drives at Indian Institute of Technology Mandi
Mandi, Himachal Pradesh
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About the Specialization
What is Power Electronics and Drives at Indian Institute of Technology Mandi Mandi?
This Power Electronics and Drives (PED) program at IIT Mandi focuses on advanced concepts and applications crucial for modern electrical systems. It encompasses the design, control, and implementation of power electronic converters and electric drive systems, which are vital for renewable energy integration, electric vehicles, and industrial automation in the rapidly evolving Indian energy sector. The program emphasizes both theoretical foundations and practical skills.
Who Should Apply?
This program is ideal for electrical and electronics engineering graduates seeking to specialize in cutting-edge power systems. It is also well-suited for working professionals in power, energy, or manufacturing sectors aiming to upgrade their skills for roles in R&D, design, or system integration. Aspiring researchers looking to contribute to sustainable energy solutions and advanced motor control technologies in India will find this program highly beneficial.
Why Choose This Course?
Graduates of this program can expect to pursue high-demand careers in India''''s booming power sector, including electric vehicle manufacturing, renewable energy development, and industrial automation. Entry-level salaries typically range from INR 7-12 LPA, with experienced professionals earning significantly more. The strong theoretical and practical grounding prepares students for roles in R&D, design engineering, and project management at leading Indian and multinational companies, aligning with certifications in power systems and drives.
Student Success Practices
Foundation Stage
Master Core Power Electronics & Drives Fundamentals- (Semester 1)
Dedicate significant time in the first semester to thoroughly understand the theoretical foundations of Advanced Power Electronics, Advanced Electric Drives, and Microcontrollers for Power Electronics. Actively participate in lab sessions to gain hands-on experience with converters and drive control. Form study groups to discuss complex concepts and solve problems collaboratively.
Tools & Resources
NPTEL courses on Power Electronics and Drives, MATLAB/Simulink for simulations, Textbooks like Rashid, Mohan, Krause, IIT Mandi''''s departmental labs
Career Connection
A strong foundation ensures you grasp advanced topics in subsequent semesters and provides a solid base for technical interviews and thesis work in core PED companies.
Enhance Simulation and Programming Skills- (Semester 1)
Alongside theoretical courses, actively engage in developing proficiency in simulation tools essential for power electronics. Practice coding for microcontrollers used in control applications. Explore open-source projects related to power electronics control and contribute to them.
Tools & Resources
MATLAB/Simulink, PSCAD, ETAP for power system simulation, C/C++ for embedded systems, Python for data analysis, GitHub for open-source projects
Career Connection
Proficiency in simulation and programming is highly valued in R&D roles, enabling you to design, analyze, and optimize power electronic systems effectively.
Engage with Departmental Research & Faculty- (Semester 1)
Attend departmental seminars, workshops, and research presentations. Proactively connect with faculty members whose research interests align with yours. This early engagement can help you identify potential M.Tech thesis advisors and research topics, fostering a deeper understanding of current research trends.
Tools & Resources
IIT Mandi SCEE Research Group pages, IEEE Xplore, Google Scholar for research papers
Career Connection
Early research exposure cultivates critical thinking and problem-solving skills, crucial for both academic and industrial R&D careers, and helps in shaping a high-quality thesis.
Intermediate Stage
Deepen Understanding of Drive Control & Devices- (Semester 2)
In the second semester, focus intensely on ''''Control of Electric Drives'''' and ''''Power Semiconductor Devices''''. Understand the intricate control algorithms and the physical characteristics of devices. Experiment with different control strategies in the lab and simulate their performance under various conditions to build practical expertise.
Tools & Resources
Laboratory equipment for drive control experiments, Manufacturer datasheets for power devices, Academic papers on FOC/DTC, ANSYS Maxwell for device simulation
Career Connection
Expertise in drive control and power devices is directly applicable to design and development roles in electric vehicle, industrial automation, and power converter manufacturing industries.
Strategically Choose Electives for Specialization- (Semester 2)
Select electives like Electric Vehicle Technology, Smart Grids, or Electrical Machine Design based on your career aspirations. Use these courses to build a concentrated area of expertise within Power Electronics and Drives. Network with industry professionals and alumni to understand industry demands for specific elective areas.
Tools & Resources
IIT Mandi Career Development Cell resources, LinkedIn for industry networking, Industry reports on emerging technologies
Career Connection
Targeted elective choices make you a more attractive candidate for specialized roles and help carve out a niche in specific industries, increasing your employability.
Initiate M.Tech Thesis Research and Planning- (Semester 2)
While formally the thesis starts later, use Semester 2 to finalize your thesis topic, conduct preliminary literature reviews, and connect with your potential thesis advisor. Draft a clear research proposal outlining objectives, methodology, and expected outcomes. This proactive approach ensures a smooth transition into Part-I of the thesis.
Tools & Resources
Mendeley/Zotero for reference management, LaTeX for document preparation, Regular meetings with potential advisors
Career Connection
A well-planned thesis is critical for demonstrating your research capabilities, often leading to publications and showcasing your expertise to potential employers.
Advanced Stage
Execute High-Impact M.Tech Thesis Project- (Semester 3-4)
Devote significant effort to your M.Tech Thesis (Part-I and Part-II) in the final two semesters. Aim for original contributions, publishable results, and robust experimental validation. Regularly consult with your advisor, seek peer feedback, and attend relevant conferences to refine your work and present findings effectively.
Tools & Resources
Advanced simulation software, High-power laboratory equipment, Research journals (IEEE, IET), Conference participation (e.g., PEDES, IECON)
Career Connection
A strong thesis with impactful results is your biggest asset for placements, R&D roles, or further doctoral studies, showcasing your ability to conduct independent, high-level research.
Develop Professional Presentation and Communication Skills- (Semester 3-4)
Practice presenting your research work effectively, both verbally and through technical reports. Participate in departmental colloquia, thesis defense preparations, and consider presenting at national/international conferences. Strong communication skills are vital for conveying complex technical ideas to diverse audiences.
Tools & Resources
PowerPoint/Beamer for presentations, Grammarly for technical writing, Public speaking workshops
Career Connection
Excellent presentation skills are crucial for technical lead roles, client interactions, and communicating research findings, boosting your professional impact.
Actively Engage in Placement Preparation and Networking- (Semester 3-4)
Attend placement preparation workshops, mock interviews, and resume building sessions organized by the career development cell. Network with alumni and industry professionals through LinkedIn and career fairs. Tailor your resume and interview responses to highlight your specialization in Power Electronics and Drives and your thesis contributions.
Tools & Resources
IIT Mandi Career Development Cell portal, LinkedIn for professional networking, Company websites for job openings, Glassdoor for interview preparation
Career Connection
Strategic placement preparation maximizes your chances of securing desirable positions in core power electronics and drives companies, ensuring a smooth transition from academics to industry.
Program Structure and Curriculum
Eligibility:
- B.E./B.Tech. in Electrical Engineering/Electrical & Electronics Engineering/Power Engineering/Instrumentation Engineering, or M.Sc. (Physics) followed by a B.Tech. in relevant disciplines, with a valid GATE score. Candidates must meet the minimum score and academic performance criteria as per institute norms.
Duration: 2 years (4 semesters)
Credits: 60 Credits
Assessment: Assessment pattern not specified
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE501 | Advanced Power Electronics | Core | 3 | Switching power converters, PWM techniques for inverters, Resonant converters, Multilevel inverters, Grid-connected converters, Soft-switching techniques |
| EE503 | Advanced Electric Drives | Core | 3 | Dynamics of electric machines, DC motor drives, Induction motor drives (scalar control), Synchronous motor drives, Energy efficiency in drives |
| EE505 | Power Electronics and Drives Lab | Lab | 3 | Converter experimental setup, Inverter control implementation, Motor speed control experiments, PWM generation and analysis, Device characterization and testing |
| EE506 | Microcontrollers for Power Electronics | Core | 3 | Digital control basics, DSP/Microcontroller architecture, PWM generation using microcontrollers, Interfacing and peripherals, Real-time control algorithms |
| EE515 | Renewable Energy Systems | Elective | 3 | Solar PV systems, Wind energy conversion systems, Grid integration issues of renewables, Power electronic converters for renewables, Energy storage systems and their control |
| EE510 | Smart Grids | Elective | 3 | Smart grid architecture and standards, Renewable energy integration in grids, Demand-side management strategies, Microgrids and distributed generation, Communication technologies in smart grids |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE502 | Control of Electric Drives | Core | 3 | Modeling of AC and DC machines, Field-Oriented Control (FOC) of induction motors, Direct Torque Control (DTC), Sensorless control techniques, Observers and state estimation for drives |
| EE504 | Power Semiconductor Devices | Core | 3 | Physics of power devices (diodes, MOSFETs, IGBTs, Thyristors), Device characteristics and limitations, Switching transients and protection circuits, Gate drive circuits and their design, Thermal management of power devices |
| EE518 | Electric Vehicle Technology | Elective | 3 | EV/HEV architectures and propulsion systems, Electric machines for traction applications, Battery management systems and charging, Power electronics in electric vehicles, Vehicle dynamics and control |
| EE512 | Electrical Machine Design | Elective | 3 | Principles of machine design, Design of induction motors, Design of synchronous machines, Thermal design considerations and cooling, Computer-aided design tools |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE699 | M.Tech Thesis Part-I | Project | 15 | Literature Survey and Gap Identification, Problem Formulation and Scope Definition, Methodology Design and Experimental Setup, Preliminary Simulations and Data Collection, Progress Reporting and Mid-term Evaluation |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE699 | M.Tech Thesis Part-II | Project | 15 | Advanced Research Work and Analysis, Detailed Simulations and Experimental Validation, Result Interpretation and Discussion, Thesis Writing and Documentation, Final Thesis Defense and Presentation |
