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M-TECH in Power Electronics at Indian Institute of Technology Roorkee
Haridwar, Uttarakhand
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About the Specialization
What is Power Electronics at Indian Institute of Technology Roorkee Haridwar?
This Power Electronics, Electrical Drives & Power Systems program at IIT Roorkee focuses on advanced concepts in power conversion, motor control, and modern power system operation. It addresses the growing demand for efficient energy management, renewable energy integration, and smart grid solutions in the Indian industrial and infrastructure sectors, emphasizing both theoretical depth and practical applications relevant to India''''s energy transition.
Who Should Apply?
This program is ideal for electrical engineering graduates with a strong foundation in power systems and electronics seeking entry into R&D, design, or operational roles in the energy sector. It also caters to working professionals aiming to upskill in emerging areas like electric vehicles, smart grids, and renewable energy, or those aspiring for academic and research careers in these specialized fields within India.
Why Choose This Course?
Graduates of this program can expect to pursue rewarding careers in PSUs like Power Grid, NTPC, BHEL, private energy companies, and electric vehicle manufacturers in India. Typical salary ranges for fresh M.Tech graduates in India could be 8-15 LPA, with experienced professionals earning significantly more. They gain expertise crucial for India''''s push towards sustainable energy and can contribute to advanced technology development.
Student Success Practices
Foundation Stage
Master Core Technical Fundamentals- (Semester 1-2)
Diligently study advanced power electronics, electrical drives, and control systems. Utilize textbooks, NPTEL lectures, and actively participate in lectures and tutorial sessions to build a strong theoretical base for the specialization.
Tools & Resources
Course textbooks, NPTEL, Peer study groups, IITR library resources
Career Connection
Forms the bedrock for understanding complex industry problems and for excelling in technical interviews for core engineering roles in the power sector.
Develop Hands-on Lab & Simulation Proficiency- (Semester 1-2)
Maximize learning from Power Electronics Lab-I & II (EED-511, EED-512). Gain practical experience with power converter design, motor control, and system integration. Develop strong simulation skills using industry-standard software.
Tools & Resources
MATLAB/Simulink, PSIM, dSPACE, Laboratory equipment, Lab manuals
Career Connection
Essential for R&D, design, and testing engineer positions where practical application of theory is critical in power electronics and drives companies.
Engage with Departmental Research & Electives- (Semester 1-2)
Attend research seminars by faculty and Ph.D. scholars to understand ongoing work in power electronics and power systems. Carefully choose electives that align with your career interests (e.g., Renewable Energy Systems, Smart Grid) to gain specialized knowledge early on.
Tools & Resources
Departmental seminar schedules, Faculty research profiles, Course catalogs for electives
Career Connection
Helps in identifying a suitable project area for your thesis and signals specialized interests to potential employers in related industries.
Intermediate Stage
Initiate & Drive Project Dissertation Part-I- (Semester 3)
Begin EED-601 Project Dissertation Part-I with a clear problem statement and comprehensive literature review. Actively engage with your supervisor, conduct preliminary simulations, and aim for initial results, laying a strong foundation for your M.Tech thesis.
Tools & Resources
IEEE Xplore, Scopus, Google Scholar, Specific simulation software (e.g., PLECS, Ansys), IITR research labs
Career Connection
Demonstrates research aptitude, problem-solving skills, and contributes significantly to your resume for R&D roles or further academic pursuits.
Seek Industry Internships & Exposure- (Semester 3 (or preceding summer break))
Actively pursue summer or part-time internships at companies relevant to power electronics design, electrical drives, or smart grid technologies. This provides invaluable real-world experience and networking opportunities.
Tools & Resources
IITR Placement Cell, Professional networks (LinkedIn), Company career portals
Career Connection
Bridges the gap between academia and industry, often leading to pre-placement offers (PPOs) or strong recommendations for full-time roles in your chosen field.
Build a Professional Network- (Semester 3)
Attend conferences, workshops, and industry events (even online ones) related to your specialization. Connect with industry professionals, alumni, and researchers to gain insights and explore opportunities in the power sector.
Tools & Resources
LinkedIn, Professional bodies like IEEE, National/international conferences (e.g., PEDES, ICPE)
Career Connection
Opens doors to mentorship, job opportunities, and helps you stay abreast of industry advancements and technological shifts.
Advanced Stage
Excel in Project Dissertation Part-II & Thesis Submission- (Semester 4)
Conclude EED-602 Project Dissertation Part-II by meticulously analyzing results, writing a comprehensive thesis, and preparing for a strong defense. Aim for a publication in a reputed journal or conference if the research merits it.
Tools & Resources
LaTeX/Word for thesis writing, Presentation software, Statistical analysis tools, Academic integrity guidelines
Career Connection
The culmination of your M.Tech, providing a tangible output for showcasing your expertise, critical for placements and higher studies (Ph.D.).
Intensive Placement Preparation- (Semester 4)
Dedicate significant time to resume building, mock interviews (technical and HR), and aptitude test preparation. Tailor your applications to specific roles in power electronics design, embedded control, or power system analysis based on your specialization.
Tools & Resources
IITR Placement Cell, Online aptitude platforms, Company-specific interview guides, Peer interview practice
Career Connection
Maximizes your chances of securing a high-quality placement in core engineering companies, PSUs, or research organizations.
Explore Entrepreneurship & Innovation- (Semester 4)
For those with an entrepreneurial bent, leverage IITR''''s innovation ecosystem (e.g., Technology Incubation & Entrepreneurship Development Society - TIEDS) to explore commercializing research ideas or developing startups in the energy domain.
Tools & Resources
IITR Incubation Cell, Startup mentorship programs, Government schemes for startups (e.g., Startup India)
Career Connection
Provides an alternative career path, fosters leadership, and contributes to India''''s innovation economy in the high-growth power and energy sector.
Program Structure and Curriculum
Eligibility:
- B.Tech. in Electrical Engineering. Mandatory GATE score in EE. Minimum 6.00 CPI or 60% marks for Gen/OBC; 5.50 CPI or 55% for SC/ST/PwD. (Source: IIT Roorkee M.Tech Admission Notice 2024)
Duration: 2 years (4 semesters)
Credits: 92 Credits
Assessment: Assessment pattern not specified
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EED-501 | Advanced Power Electronics | Core | 6 | Power Semiconductor Devices, Converter Topologies (AC-DC, DC-DC, DC-AC), PWM Control Techniques, Resonant and Soft-Switching Converters, Multilevel Converters, Applications in Renewable Energy |
| EED-503 | Advanced Control Systems | Core | 6 | State-Space Analysis, Nonlinear Control Systems, Optimal Control Theory, Adaptive Control, Robust Control Design, System Identification |
| EED-505 | Electrical Drives | Core | 6 | Dynamics of Electrical Machines, DC Motor Drives Control, Induction Motor Drives (Scalar & Vector Control), Synchronous Motor Drives, Special Machine Drives, Industrial Drive Applications |
| EED-511 | Power Electronics Lab-I | Lab | 4 | Device Characterization, DC-DC Converter Experiments, Inverter Control, AC-DC Rectifier Experiments, Simulation using MATLAB/PSIM, Closed-loop Control Implementation |
| Elective - I | Elective - I | Elective | 6 | Topics depend on the chosen elective from the departmental pool |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EED-502 | Power System Dynamics and Control | Core | 6 | Power System Stability Concepts, Synchronous Machine Modeling, Excitation Systems and Governors, Transient Stability Analysis, Voltage Stability and Control, Power System Oscillations |
| EED-504 | HVDC and FACTS | Core | 6 | HVDC Transmission Principles, HVDC Converter Configurations, Control of HVDC Systems, Flexible AC Transmission Systems (FACTS), SVC, STATCOM, TCSC, UPFC, Harmonic Mitigation in Power Systems |
| EED-512 | Power Electronics Lab-II | Lab | 4 | Grid-Connected Inverters, Active Power Factor Correction, High-Frequency Converters, Electric Vehicle Charging Systems, Renewable Energy Integration, Real-time Control Implementation |
| Elective - II | Elective - II | Elective | 6 | Topics depend on the chosen elective from the departmental pool |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EED-601 | Project Dissertation Part-I | Project | 20 | Literature Review and Problem Identification, Research Objectives and Methodology, Experimental Setup Design, Simulation and Modeling, Data Collection and Analysis Plan, Interim Report and Presentation |
| Elective - III | Elective - III | Elective | 6 | Topics depend on the chosen elective from the departmental pool |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EED-602 | Project Dissertation Part-II | Project | 20 | Detailed Experimental Work, Results Analysis and Discussion, Thesis Writing and Documentation, Final Presentation and Defense, Validation of Research Outcomes, Future Scope of Work |
