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M-TECH in Power Electronics And Control at Adi Shankara Institute of Engineering and Technology
Ernakulam, Kerala
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About the Specialization
What is Power Electronics and Control at Adi Shankara Institute of Engineering and Technology Ernakulam?
This Power Electronics and Control program at Adi Shankara Institute of Engineering and Technology focuses on equipping students with advanced knowledge in designing, analyzing, and controlling power electronic systems. It addresses the growing need for skilled engineers in India''''s energy sector, emphasizing applications in renewable energy integration, electric vehicles, smart grids, and industrial automation. The program is differentiated by its strong foundation in both theoretical concepts and practical applications, preparing graduates for cutting-edge challenges in the field.
Who Should Apply?
This program is ideal for fresh electrical engineering graduates seeking entry into the power sector''''s advanced domains, working professionals looking to upskill in areas like power converter design or motor control, and career changers aiming to transition into high-demand industries such as renewable energy, electric vehicle manufacturing, or smart grid deployment. Prerequisites typically include a B.Tech in Electrical & Electronics Engineering or a closely related field, demonstrating a solid understanding of fundamental electrical engineering principles.
Why Choose This Course?
Graduates of this program can expect promising career paths in R&D, design, and manufacturing roles across various Indian industries. Typical roles include Power Electronics Design Engineer, Control Systems Engineer, EV Powertrain Engineer, and Renewable Energy System Integrator. Entry-level salaries in India range from INR 4-7 LPA, with experienced professionals earning INR 10-25+ LPA in leading companies and PSUs. The program aligns with industry needs, potentially leading to professional certifications in power systems or control engineering, enhancing growth trajectories.
Student Success Practices
Foundation Stage
Master Core Concepts through Problem Solving- (Semester 1-2)
Dedicate time to solving a wide variety of problems in Advanced Control Theory and Power Electronic Converters. Utilize textbooks, online resources like NPTEL lectures, and past university exam papers. Focus on understanding the mathematical models and underlying physics.
Tools & Resources
NPTEL courses, Standard textbooks (e.g., K. Ogata for Control, N. Mohan for Power Electronics), KTU question banks
Career Connection
Strong conceptual understanding forms the bedrock for designing robust power electronic systems and control algorithms, crucial for R&D and design engineer roles.
Excel in Laboratory Skills and Simulation- (Semester 1-2)
Actively participate in Power Electronics and Control Lab I and II. Beyond performing experiments, aim to understand the ''''why'''' behind each step. Become proficient in simulation tools like MATLAB/Simulink and PSIM/PLECS to model and analyze circuits before hardware implementation.
Tools & Resources
MATLAB/Simulink, PSIM/PLECS, Lab equipment manuals, Microcontroller/DSP development boards
Career Connection
Practical skills in simulation and hardware implementation are highly valued by industries for prototyping, testing, and debugging power electronic systems and drives.
Engage in Technical Seminars and Literature Review- (Semester 1-2)
For the Research Methodology and IPR course and the Seminar, delve deep into recent research papers in your area of interest within power electronics. Attend departmental seminars and workshops, critically analyze presented topics, and practice effective technical communication.
Tools & Resources
IEEE Xplore, Google Scholar, Departmental seminar series, Presentation software
Career Connection
Developing strong research and presentation skills is vital for higher studies, R&D positions, and effectively communicating complex technical ideas in any professional setting.
Intermediate Stage
Pursue Elective Specialization and Mini-Projects- (Semester 2-3)
Strategically choose electives that align with your career interests, such as Electric Vehicles, Smart Grids, or Industrial Drives. Beyond coursework, initiate small-scale mini-projects related to these electives, perhaps building a small converter or control system model.
Tools & Resources
Elective subject textbooks, Open-source hardware platforms (e.g., Arduino, Raspberry Pi for control), Component suppliers like Mouser/Digi-Key for practical components
Career Connection
Specialized knowledge and practical project experience make you a more attractive candidate for focused roles in emerging fields like EV technology or renewable energy integration.
Seek Industrial Training/Internship- (Between Semester 2 and 3)
Actively search for and undertake industrial training or internships, as mandated by the curriculum (2020EEPC306). Focus on gaining hands-on experience in areas like power plant operations, manufacturing unit maintenance, or R&D labs dealing with power electronics.
Tools & Resources
College placement cell, Online internship portals (Internshala, LinkedIn), Industry contacts
Career Connection
Internships provide invaluable industry exposure, professional networking opportunities, and often lead to pre-placement offers, significantly boosting employability in India.
Participate in Technical Competitions and Workshops- (Semester 2-3)
Join national-level technical competitions (e.g., organized by IEEE, IET, or specific industries) related to power electronics, robotics, or energy. Attend specialized workshops to learn new software, hardware platforms, or advanced manufacturing techniques relevant to your field.
Tools & Resources
IEEE student branch activities, Technical clubs, Online learning platforms (Coursera, edX for specialized courses)
Career Connection
Participation demonstrates initiative, problem-solving abilities, and practical skills to potential employers, setting you apart in a competitive job market.
Advanced Stage
Excel in Project Phase I & II (Thesis Work)- (Semester 3-4)
Treat your M.Tech Project (2020EEPC301, 2020EEPC401) as a cornerstone of your specialization. Select a challenging topic with real-world relevance, conduct thorough research, and aim for publishable quality. Collaborate effectively with your guide and peers.
Tools & Resources
Academic supervisor, University library resources, Advanced simulation tools (ANSYS, COMSOL for FEA), Access to lab facilities
Career Connection
A strong, impactful thesis project is a key differentiator for R&D roles, academic positions, and demonstrates your ability to independently solve complex engineering problems.
Prepare for Placements and Interviews- (Semester 3-4)
Start early with placement preparation, focusing on technical aptitude (especially in power electronics, control, and electrical machines), logical reasoning, and communication skills. Practice coding relevant to embedded systems if pursuing that path. Develop a strong portfolio of your projects.
Tools & Resources
Placement training sessions, Mock interview platforms, GeeksforGeeks for aptitude/coding, Resume/CV building workshops
Career Connection
Thorough preparation ensures you can articulate your technical knowledge and project experience effectively, leading to successful placements in core electrical companies or related tech industries.
Build a Professional Network- (Throughout the program, intensifying in Semester 4)
Network with faculty, alumni, industry professionals encountered during internships, and guest speakers. Attend industry conferences and job fairs in India. Leverage platforms like LinkedIn to connect with professionals in power electronics and control.
Tools & Resources
LinkedIn, Alumni network events, Industry conferences (e.g., ELECRAMA, India Smart Grid Week)
Career Connection
A strong professional network can open doors to job opportunities, mentorship, and collaborative research, which are invaluable for long-term career growth in India''''s dynamic electrical sector.
Program Structure and Curriculum
Eligibility:
- B.Tech/B.E. in Electrical & Electronics Engineering/Electrical Engineering/Applied Electronics/Electronics and Instrumentation or equivalent degree with a minimum of 60% marks/6.5 CGPA (for General category) or 55% marks/6.0 CGPA (for SC/ST) in the qualifying examination, as per KTU norms.
Duration: 4 Semesters
Credits: 67 Credits
Assessment: Internal: 40% (for theory subjects, based on tests, assignments, seminars), External: 60% (for theory subjects, University examination). Lab, Seminar, Industrial Training, and Project are 100% internal assessment.
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EEPC101 | Advanced Control Theory | Core | 3 | State Space Analysis, Linear Systems, Non-linear Systems, Describing Functions, Optimal Control Theory |
| 2020EEPC102 | Power Electronic Converters | Core | 3 | DC-DC Converters, AC-DC Converters, DC-AC Inverters, Resonant Converters, Multilevel Converters |
| 2020MA6001 | Applied Mathematics for Electrical Engineers | Core (Common) | 4 | Linear Algebra, Vector Calculus, Probability and Statistics, Transform Techniques, Numerical Methods |
| 2020EEPC103 | Elective I: Advanced Power System Operation and Control | Elective | 3 | Power System Security, Optimal Power Flow, Voltage Stability, Wide Area Monitoring, Renewable Energy Integration |
| 2020EEPC104 | Elective I: Modelling and Analysis of Electrical Machines | Elective | 3 | Generalized Machine Theory, DC Machine Modeling, Induction Machine Modeling, Synchronous Machine Modeling, Special Machines |
| 2020EEPC105 | Elective I: Embedded Systems for Power Applications | Elective | 3 | Embedded Processors, RTOS, Interfacing, Communication Protocols, Industrial Applications |
| 2020EEPC106 | Power Electronics and Control Lab I | Lab | 2 | Converter Circuit Simulation, DSP/Microcontroller Programming, Power Device Characterization, Motor Control Experiments, Hardware Implementation |
| 2020EEPC107 | Research Methodology and IPR | Core | 2 | Research Problem Formulation, Data Collection, Statistical Analysis, Report Writing, Intellectual Property Rights |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EEPC201 | Dynamics of Electrical Drives | Core | 3 | DC Motor Drives, Induction Motor Drives, Synchronous Motor Drives, Sensorless Control, Multi-quadrant Operation |
| 2020EEPC202 | Digital Control of Power Electronic Systems | Core | 3 | Sampling Theory, Digital Controllers, DSP in Power Electronics, FPGA based Control, Real-time Implementation |
| 2020EEPC203 | Elective II: Switched Mode Power Supplies | Elective | 3 | SMPS Topologies, Control Techniques, Magnetics Design, EMI/EMC, Power Factor Correction |
| 2020EEPC204 | Elective II: Flexible AC Transmission Systems and HVDC | Elective | 3 | FACTS Devices, STATCOM, UPFC, HVDC Systems, Control of HVDC |
| 2020EEPC205 | Elective II: Artificial Intelligence in Power Systems | Elective | 3 | Neural Networks, Fuzzy Logic, Genetic Algorithms, Machine Learning, Power System Applications |
| 2020EEPC206 | Elective III: Energy Management and Auditing | Elective | 3 | Energy Conservation, Renewable Energy Systems, Energy Audit Procedures, Demand Side Management, Economic Analysis |
| 2020EEPC207 | Elective III: Control of Grid-Connected Power Converters | Elective | 3 | Grid Synchronization, Active and Reactive Power Control, Harmonic Mitigation, Grid Code Requirements, Microgrids |
| 2020EEPC208 | Elective III: EMI and EMC in Power Electronic Systems | Elective | 3 | EMI Sources, Coupling Mechanisms, Shielding Techniques, Filtering, Standards and Regulations |
| 2020EEPC209 | Power Electronics and Control Lab II | Lab | 2 | Advanced Converter Design, Drive System Control, Grid-Connected Inverter Testing, MATLAB/Simulink Simulation, Real-time Controller Implementation |
| 2020EEPC210 | Seminar | Project/Seminar | 2 | Literature Survey, Technical Presentation, Report Writing, Research Communication, Critical Analysis |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EEPC301 | Project Phase I | Project | 6 | Problem Identification, Literature Review, Methodology Development, Preliminary Design, Interim Report |
| 2020EEPC302 | Elective IV: Advanced Topics in Smart Grid | Elective | 3 | Smart Grid Architecture, Advanced Metering Infrastructure, Distributed Generation, Cyber Security, Smart Grid Standards |
| 2020EEPC303 | Elective IV: Electrical System Design for Industries | Elective | 3 | Load Estimation, Power Distribution, Motor Control Centers, Protection Systems, Safety Regulations |
| 2020EEPC304 | Elective IV: Power Electronics for Electric Vehicles | Elective | 3 | EV Architectures, Battery Management Systems, Charging Technologies, Motor Control for EVs, Auxiliary Systems |
| 2020EEPC305 | Elective IV: Real-time Control of Power Systems | Elective | 3 | SCADA, PMU, WAMS, EMS, AGC, State Estimation |
| 2020EEPC306 | Industrial Training/Internship | Internship | 2 | Industry Exposure, Practical Skill Development, Project Implementation, Professional Networking, Report Submission |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EEPC401 | Project Phase II | Project | 16 | Prototype Development, Experimental Validation, Data Analysis, Thesis Writing, Viva Voce |
