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M-TECH in Power Electronics at Viswajyothi College of Engineering and Technology
Ernakulam, Kerala
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About the Specialization
What is Power Electronics at Viswajyothi College of Engineering and Technology Ernakulam?
This Power Electronics program at Viswajyothi College of Engineering and Technology focuses on the design, control, and application of power electronic converters for efficient energy conversion. India''''s growing demand for electric vehicles, robust renewable energy integration, and smart grids makes this specialization highly relevant, driving innovation in efficient power management systems. The program equips students with advanced skills vital for shaping the future of energy infrastructure in the country.
Who Should Apply?
This program is ideal for electrical engineering graduates with a keen interest in power conversion technologies, renewable energy systems, and electric drives. It also suits working professionals seeking to upskill in cutting-edge power electronics for careers in research and development, manufacturing, or power utilities. Candidates with a strong foundation in circuit theory, control systems, and a desire to contribute to India''''s energy transition are particularly well-suited.
Why Choose This Course?
Graduates of this program can expect promising career paths in Indian companies like Siemens, ABB, L&T, major PSUs (e.g., NTPC, BHEL), and emerging startups in the EV and renewable energy sectors. Roles typically include Power Electronics Engineer, R&D Engineer, or System Design Specialist, with entry-level salaries ranging from INR 5-8 LPA and significantly higher for experienced professionals. The skills acquired align with certifications in power system analysis and embedded control.
Student Success Practices
Foundation Stage
Master Core Mathematical and Electrical Concepts- (Semester 1-2)
Dedicate significant time to thoroughly understand advanced engineering mathematics, fundamental power electronic converter principles, and electrical machine modeling. Utilize online platforms like NPTEL for in-depth lectures and practice problem-solving. Form study groups to discuss complex topics and clarify doubts proactively.
Tools & Resources
NPTEL courses (Power Electronics, Advanced Mathematics), Reference textbooks (e.g., M.H. Rashid, Ned Mohan), MATLAB/Simulink for basic simulations
Career Connection
A strong foundation in these core areas is crucial for advanced subject comprehension and forms the bedrock for solving complex industry problems in power system design and control, directly impacting roles in R&D and product development.
Hands-on Simulation and Lab Skill Development- (Semester 1-2)
Actively participate in Power Electronics Lab sessions. Beyond assigned experiments, explore additional simulation exercises using software like PSCAD, ETAP, and MATLAB/Simulink. Aim to simulate real-world scenarios, analyze component behavior, and validate theoretical concepts under various operating conditions.
Tools & Resources
MATLAB/Simulink, PSCAD/EMTDC, ETAP, College''''s power electronics lab equipment
Career Connection
Practical simulation and hardware implementation skills are highly valued in design and R&D roles within companies developing power electronic devices and systems in India. Proficiency here accelerates problem-solving and validation of new designs.
Engage with Research Methodology and IPR- (Semester 1-2)
Treat the Research Methodology and IPR audit course as a crucial skill-building opportunity. Learn effective literature review strategies, methods for critical analysis of research papers, and proper citation techniques. Understand Intellectual Property Rights to legally safeguard future innovations and research outcomes.
Tools & Resources
Scopus, IEEE Xplore, Google Scholar, IPR India website
Career Connection
Developing strong research acumen and IPR awareness is essential for aspiring R&D engineers, academics, and innovators, enabling them to contribute meaningfully to technological advancement and protect their intellectual output in India''''s competitive landscape.
Intermediate Stage
Deep Dive into Specialization Electives- (Semester 2-3)
Strategically choose electives that align with your specific career aspirations within Power Electronics. For example, if interested in Electric Vehicles, focus on ''''Electric Vehicles and Charging Infrastructure''''. Conduct additional self-study beyond classroom material through specialized journals and advanced online courses.
Tools & Resources
IEEE Transactions on Power Electronics, Coursera/edX advanced courses, Specialized reference books
Career Connection
Strategic specialization through electives creates a distinct professional profile, making you a more attractive candidate for niche roles in high-demand sectors like renewable energy integration, electric mobility, or smart grid technology development in India.
Initiate and Execute Mini and Major Projects- (Semester 2-3)
Start identifying potential mini-project and Project Phase I topics early, ideally with an industry relevance or societal impact. Collaborate effectively with peers and faculty to refine ideas, conduct extensive literature reviews, and begin preliminary design and simulations. Focus on clearly defining the problem and proposing a viable solution.
Tools & Resources
Project management tools, Advanced simulation software (e.g., Ansys, COMSOL), Access to college fabrication labs and resources
Career Connection
Well-executed project work, especially with industry relevance, is a powerful resume builder. It showcases your ability to apply theoretical knowledge to practical problems, a key requirement for R&D and product development roles in Indian industries.
Seek Industrial Training/Internship Opportunities- (Semester 2-3)
Actively search for internships during summer breaks or leverage the dedicated audit course in Semester 3. Aim for opportunities in prominent Indian companies or MNCs with R&D centers in India, focusing on power electronics manufacturing, design, or research. This provides invaluable real-world experience and networking.
Tools & Resources
College placement cell services, LinkedIn, Internshala, Company career pages for specific job roles
Career Connection
Internships are often direct pathways to pre-placement offers, allowing you to gain critical industry exposure, understand corporate culture, and build a professional network, significantly boosting employability upon graduation.
Advanced Stage
Excel in Final Year Project and Thesis Writing- (Semester 4)
Treat Project Phase II as the capstone of your M.Tech journey. Strive for innovative solutions, meticulous experimentation, and thorough analysis of results. Focus on writing a high-quality thesis, adhering to academic standards, as this comprehensively showcases your research and technical communication skills to potential employers or doctoral programs.
Tools & Resources
LaTeX for professional thesis writing, Plagiarism checkers, Grammarly for academic writing support
Career Connection
A well-executed and documented final project significantly enhances your resume for R&D roles, doctoral studies, and can even lead to patent opportunities or startup ventures, demonstrating advanced technical capability and problem-solving skills.
Prepare for Placements and Professional Interviews- (Semester 4)
Begin placement preparation early by polishing your resume, practicing technical interview questions related to power electronics, electrical machines, and control systems. Actively participate in mock interviews and aptitude tests offered by the college placement cell or online platforms. Focus on specific roles in the power and energy sector.
Tools & Resources
College placement coaching/workshops, Online aptitude test platforms, Technical interview guides for electrical engineers
Career Connection
Proactive and targeted placement preparation directly increases your chances of securing desirable job offers from top companies in the power electronics domain, ensuring a smooth and successful transition from academics to a professional career.
Network and Engage with Professional Bodies- (Semester 3-4)
Attend relevant industry seminars, workshops, and conferences (e.g., those sponsored by IEEE, IET). Network actively with professionals, researchers, and alumni in the power electronics field. Consider joining student chapters of professional organizations to expand your horizons, find mentors, and stay updated on industry trends.
Tools & Resources
IEEE Power Electronics Society (PELS), LinkedIn professional groups, National and international conference websites
Career Connection
Networking opens doors to hidden job opportunities, mentorship, and collaborative projects. Staying connected with professional bodies ensures you are aware of the latest industry trends and technological advancements, significantly enhancing your long-term career growth in the dynamic power sector.
Program Structure and Curriculum
Eligibility:
- B.Tech/B.E. in Electrical & Electronics Engineering or equivalent from a recognized university, with a minimum specified percentage/CGPA as per KTU norms. Admission is typically through GATE score or an equivalent entrance examination.
Duration: 4 semesters / 2 years
Credits: 63 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EPE101 | Advanced Engineering Mathematics | Core | 4 | Linear Algebra and Matrices, Calculus of Variations, Probability and Random Processes, Transform Techniques (Laplace, Fourier, Z), Numerical Methods and Optimization |
| 2020EPE102 | Power Electronic Converters | Core | 4 | AC-DC Controlled Converters, DC-DC Switched Mode Converters, DC-AC Inverters (PWM Techniques), Multilevel Inverters and Topologies, Resonant Converters |
| 2020EPE103 | Modelling and Analysis of Electrical Machines | Core | 4 | Reference Frame Theory, Dynamic Modelling of DC Machines, Dynamic Modelling of Induction Machines, Dynamic Modelling of Synchronous Machines, Special Machines and their control |
| 2020EPE104E | Elective I (e.g., Advanced Digital Signal Processing) | Elective | 3 | Discrete-time Signals and Systems, Z-Transform and DFT, FIR Filter Design, IIR Filter Design, Adaptive Filtering and Applications |
| 2020EPE105 | Power Electronics Lab I | Lab | 2 | Simulation of Power Converters, Characteristics of Power Semiconductor Devices, Control of DC-DC Converters, Inverter Switching Techniques, DSP/Microcontroller based control |
| 2020RMT101 | Research Methodology and IPR | Audit | 2 | Research Problem Formulation, Data Collection and Analysis Methods, Research Design and Ethics, Technical Report Writing, Intellectual Property Rights |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EPE201 | Power Quality | Core | 4 | Power Quality Disturbances, Harmonics and Inter-harmonics, Voltage Sags, Swells, Interruptions, Mitigation Techniques (Filters, Compensators), Active Power Filters |
| 2020EPE202 | Solid State Drives | Core | 4 | DC Motor Drives (Converter Fed), Induction Motor Drives (V/f, Vector Control), Synchronous Motor Drives, Permanent Magnet Motor Drives, Sensorless Control Techniques |
| 2020EPE203 | Control of Power Electronic Converters | Core | 4 | Linear Control Theory Review, Non-linear Control Strategies (Feedback Linearization), Digital Control of Converters, Sliding Mode Control, Fuzzy Logic and Neural Network Control |
| 2020EPE204E | Elective II (e.g., Advanced Microcontrollers and Embedded Systems) | Elective | 3 | ARM Processor Architecture, Embedded C Programming, Real-Time Operating Systems (RTOS), Interfacing with Peripherals, Communication Protocols (SPI, I2C, UART) |
| 2020EPE205E | Elective III (e.g., Distributed Generation & Smart Grid) | Elective | 3 | Renewable Energy Sources (DG), Grid Integration Challenges, Smart Grid Infrastructure, Microgrids and Islanding, Energy Storage Systems |
| 2020EPE206 | Power Electronics Lab II | Lab | 2 | Power Quality Measurement, Active Filter Implementation, Motor Drive Control Experiments, Grid-Tied Inverter Control, IoT in Power Electronics |
| 2020EPE207 | Mini Project | Project | 2 | Literature Survey and Problem Identification, System Design and Simulation, Hardware/Software Implementation, Testing and Performance Analysis, Technical Report Writing |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EPE301E | Elective IV (e.g., Renewable Energy Systems) | Elective | 3 | Solar Photovoltaic Systems, Wind Energy Conversion Systems, Biomass and Biofuel Energy, Hydro and Ocean Energy, Hybrid Renewable Energy Systems |
| 2020EPE302E | Elective V (e.g., Electric Vehicles and Charging Infrastructure) | Elective | 3 | Electric Vehicle Architectures, EV Motors and Drives, Battery Management Systems, EV Charging Technologies, Grid Integration of EVs |
| 2020EPE303 | Project Phase I | Project | 6 | Comprehensive Literature Review, Problem Definition and Scope, Methodology and Design Approach, Preliminary Simulations/Experiments, Project Planning and Schedule |
| 2020EMT002 | Industrial Training/Internship | Audit | 2 | Industry Exposure and Practices, Application of Theoretical Knowledge, Professional Skill Development, Report Preparation, Presentation of Findings |
| 2020RRP001 | Research Review Paper | Audit | 2 | Advanced Literature Search, Critical Analysis of Research Papers, Identification of Research Gaps, Scientific Writing for Publication, Peer Review Process |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 2020EPE401 | Project Phase II | Project | 12 | Detailed Design and Implementation, Experimental Setup and Data Collection, Analysis and Interpretation of Results, Thesis Writing and Documentation, Final Project Defense |
