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M-TECH in Power Electronics at Mar Baselios Institute of Technology and Science
Ernakulam, Kerala
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About the Specialization
What is Power Electronics at Mar Baselios Institute of Technology and Science Ernakulam?
This Power Electronics and Control (PEC) program at Mar Baselios Institute of Technology and Science focuses on advanced power conversion technologies, electric drives, and sophisticated control systems. Given India''''s burgeoning renewable energy sector and push for electric vehicles, this specialization is highly relevant to developing efficient and reliable energy management solutions. The program aims to equip engineers with expertise in designing and controlling modern power electronic devices and systems, crucial for sustainable technological advancement.
Who Should Apply?
This program is ideal for electrical and electronics engineering graduates seeking to specialize in the core areas of power systems, power conversion, and industrial control. It is suitable for fresh graduates with a B.Tech in EEE, EI, AE&I, IC, EE, EE&I, or AE, who aspire to work in energy, automotive, or industrial automation sectors. Working professionals looking to upskill in areas like smart grids, EV technology, or high-power industrial applications will also find this program beneficial for career progression.
Why Choose This Course?
Graduates of this program can expect to pursue rewarding careers as Power Electronics Engineers, Control System Designers, R&D Engineers in energy companies, or specialists in EV manufacturing. Entry-level salaries in India can range from INR 4-7 LPA, with experienced professionals earning upwards of INR 10-20 LPA, especially in companies focused on renewable energy, industrial automation, and electric mobility. The program also prepares students for further research or entrepreneurial ventures in the dynamic power sector.
Student Success Practices
Foundation Stage
Build Strong Theoretical Foundations- (Semester 1-2)
Focus on mastering the core concepts of advanced power electronics, digital signal processing, and control theory. Attend all lectures, actively participate in discussions, and solve complex problems from textbooks and reference materials regularly. Utilize online platforms like NPTEL for supplemental learning in specific subjects, ensuring a deep understanding of fundamental principles.
Tools & Resources
NPTEL videos, Standard textbooks (e.g., Rashid, Ogata), MATLAB/Simulink tutorials, IEEE Xplore
Career Connection
A solid theoretical base is crucial for understanding advanced topics and forms the bedrock for innovative design and troubleshooting in industry. Strong fundamentals are frequently tested in technical interviews and competitive examinations.
Hands-on Lab Skill Development- (Semester 1-2)
Actively engage in all lab sessions, including Advanced Power Electronics and Control Lab and Simulation and Control Lab. Aim to not just complete experiments but understand the underlying principles and observe the practical implications. Document findings meticulously, and seek opportunities to work on small hardware/software projects beyond the curriculum to gain practical experience.
Tools & Resources
Lab equipment, PSCAD/ETAP software, Arduino/Raspberry Pi for small projects, YouTube tutorials for practical circuits, Texas Instruments development kits
Career Connection
Practical skills are highly valued by employers in design, R&D, and manufacturing roles. Proficiency in simulation tools and hardware implementation significantly enhances employability and problem-solving abilities.
Master Research and Communication Skills- (Semester 1-2)
Take the ''''Research Methodology and IPR'''' and ''''Research Seminar'''' courses seriously. Learn how to conduct effective literature reviews, analyze data, and present technical information clearly and concisely. Practice scientific writing and presentation skills through seminar presentations, assignments, and participation in departmental talks to enhance academic and professional communication.
Tools & Resources
Mendeley/Zotero for referencing, IEEE Xplore, Google Scholar for research papers, LaTeX for scientific writing, PowerPoint/Keynote
Career Connection
Strong research and communication skills are essential for the M.Tech project work, publishing papers, and for effective professional communication in any engineering role, facilitating career growth and leadership opportunities.
Intermediate Stage
Specialization through Elective Choices- (Semester 3)
Carefully choose program electives (PEC 4 & 5) based on your specific career interests, whether it''''s modern power system operation, advanced control of converters, or other niche areas. Dive deep into the chosen elective topics, perhaps taking up mini-projects or term papers related to them. This helps in developing a specialized niche and focused expertise.
Tools & Resources
Advanced textbooks specific to electives, Recent research papers in chosen areas, Specialized simulation software (e.g., DIgSILENT PowerFactory, PLECS)
Career Connection
Specialization enhances your value proposition to employers in specific industry segments like smart grids, EV technology, or industrial automation. It demonstrates focused expertise and passion, making you a more attractive candidate for targeted roles.
Gain Real-world Industrial Experience- (Semester 3)
Maximize the learning from the Industrial Internship (232EEPE085). Actively participate in assigned tasks, ask questions, network with industry professionals, and observe how theoretical concepts are applied in an industrial setting. Prepare a detailed and insightful internship report to showcase your practical learning and contribution.
Tools & Resources
Company-specific tools and software, LinkedIn for professional networking, Internship mentors, Industry standards documentation
Career Connection
Internships are critical for bridging the gap between academia and industry. They often lead to pre-placement offers or strong recommendations, significantly boosting placement prospects and providing invaluable professional exposure.
Initiate and Plan the M.Tech Project- (Semester 3)
Dedicate significant effort to ''''Project Phase I'''' (232EEPE086). Choose a relevant and challenging research problem that aligns with current industry trends or academic interests. Conduct a thorough literature review, develop a robust methodology, and start building preliminary models or experimental setups. Regularly meet with your guide and seek feedback.
Tools & Resources
Research databases (Scopus, Web of Science), Project management tools (Trello, Asana), Collaboration platforms (Google Docs), Initial simulation tools
Career Connection
The M.Tech project is often the highlight of your resume and a major talking point in interviews. A well-defined project in Phase I demonstrates independent problem-solving and research capabilities, which are highly sought after.
Advanced Stage
Execute and Document the Final Project- (Semester 4)
For ''''Project Phase II'''' (232EEPE087), focus on meticulous execution, data collection, rigorous analysis, and validation of your research or design. Prioritize writing a high-quality thesis, ensuring clarity, logical flow, and strict adherence to academic standards. Prepare thoroughly for the project defense and viva-voce, ready to articulate your contributions.
Tools & Resources
Advanced simulation software, Experimental hardware, Data analysis tools (Python, R), Thesis writing guides, Presentation software (PowerPoint, Prezi)
Career Connection
A strong final project and thesis are direct evidence of your advanced technical skills and ability to contribute to R&D. It''''s often a key differentiator for research-oriented roles, academic positions, or higher studies, showcasing your expertise.
Prepare for Placements and Interviews- (Semester 4)
Simultaneously with project completion, initiate intensive placement preparation. This includes brushing up on core subjects (power electronics, control systems, power systems), practicing technical and HR interview questions, and diligently working on your resume and cover letters. Attend mock interviews and career workshops organized by the institute''''s placement cell.
Tools & Resources
Interview preparation platforms (GeeksforGeeks, InterviewBit), LinkedIn for professional branding, Career services cell, Resume builders
Career Connection
Effective preparation ensures you can articulate your knowledge and skills confidently, increasing your chances of securing a desirable job offer upon graduation. It''''s essential for navigating the competitive Indian job market successfully.
Explore Publication and Networking Opportunities- (Semester 4)
If your project yields publishable results, aim to submit a paper to a reputable national or international conference or journal in your field. Attend technical conferences or workshops to network with industry experts and researchers. This expands your professional network, enhances your academic profile, and keeps you abreast of the latest advancements.
Tools & Resources
IEEE, Springer, Elsevier for journal/conference submissions, Professional networking events, Alumni network platforms, ResearchGate
Career Connection
Publications and professional networking can open doors to advanced research roles, PhD opportunities, and highly specialized positions, establishing you as an expert in your field and fostering long-term career growth.
Program Structure and Curriculum
Eligibility:
- B.Tech./B.E. Degree in Electrical and Electronics Engineering (EEE), Electronics and Instrumentation (EI), Applied Electronics & Instrumentation (AE&I), Instrumentation & Control (IC), Electrical Engineering (EE), Electrical & Instrumentation (EE&I), or Applied Electronics (AE) from an AICTE approved institution/university.
Duration: 4 semesters
Credits: 60 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 232EEPE001 | Advanced Power Electronics Converters | Core | 3 | Switched-mode power converters, DC-DC Converters topologies, Multilevel Inverters (Diode-clamped, Flying capacitor, Cascaded H-bridge), PWM techniques for inverters, Advanced converter control strategies |
| 232EEPE002 | Advanced Digital Signal Processing | Core | 3 | Discrete-time signals and systems, DSP system design principles, FIR and IIR filter design, Adaptive filters and applications, Multirate signal processing |
| 232EEPE003 | Research Methodology and IPR | Core | 3 | Fundamentals of research process, Data collection and analysis techniques, Statistical methods for research, Research ethics and plagiarism, Intellectual Property Rights (IPR) and patents |
| 232EEPE004 | Computer Aided Power Systems Analysis | Program Core Elective | 3 | Power flow analysis methods, Symmetrical and unsymmetrical fault analysis, Power system stability assessment, Computer-aided simulation tools, Numerical methods for power system problems |
| 232EEPE010 | Advanced Digital Protection of Power Systems | Program Elective | 3 | Fundamentals of power system protection, Principles of digital relaying, Microprocessor-based relay design, Fault detection and classification algorithms, Adaptive protection schemes |
| 232EEPE081 | Advanced Power Electronics and Control Lab | Lab | 2 | Power converter testing and characterization, DSP implementation for control systems, Simulation experiments with power electronics, Hardware realization of control algorithms, Verification of power electronic circuits |
| 232EEPE082 | Research Seminar | Seminar | 1 | Literature review techniques, Presentation skills for research topics, Technical communication for engineers, Scientific writing standards, Effective topic selection for research |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 232EEPE007 | Control of Electric Drives | Core | 3 | DC motor drives and control, Induction motor drives (Scalar, Vector control), Permanent Magnet Synchronous Motor (PMSM) drives, Sensorless control techniques for drives, Drive system components and modeling |
| 232EEPE008 | Advanced Control Theory | Core | 3 | State-space analysis of control systems, Nonlinear control systems and their analysis, Optimal control theory (LQR, Pontryagin''''s principle), Adaptive control techniques, Robust control system design |
| 232EEPE009 | Microgrid and Distributed Generation | Core | 3 | Distributed generation technologies (PV, Wind, Fuel Cells), Microgrid architectures and operation modes, Grid integration challenges and solutions, Energy storage systems in microgrids, Microgrid control and management |
| 232EEPE011 | Optimization Techniques | Program Elective | 3 | Linear programming and Simplex method, Nonlinear programming techniques, Dynamic programming principles, Evolutionary algorithms (Genetic Algorithms, PSO), Convex optimization |
| 232EEPE012 | Soft Computing Techniques | Program Elective | 3 | Fuzzy logic and fuzzy inference systems, Artificial Neural Networks (ANN) architectures, Genetic Algorithms and evolutionary computation, Swarm intelligence (PSO, ACO), Hybrid soft computing approaches |
| 232EEPE083 | Simulation and Control Lab | Lab | 2 | MATLAB/Simulink for power electronics simulation, PSCAD/EMTDC for power system transients, ETAP for power system analysis, Control system design and implementation, Real-time simulation interfaces |
| 232EEPE084 | Mini Project | Project | 1 | Project proposal development, Design and implementation of small-scale projects, Testing and validation of prototypes, Technical report writing and documentation, Presentation of project outcomes |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 232EEPE013 | Modern Power System Operation and Control | Program Elective | 3 | SCADA and Energy Management Systems (EMS), Automatic Generation Control (AGC), Economic dispatch and unit commitment, Reactive power and voltage control, Load frequency control |
| 232EEPE014 | Advanced Control of Power Converters | Program Elective | 3 | Feedback linearization for power converters, Sliding mode control of converters, H-infinity control for robustness, Model Predictive Control (MPC) applications, Passivity-based control techniques |
| 232EEPE085 | Industrial Internship | Internship | 2 | Exposure to industrial practices, Application of theoretical knowledge in industry, Practical skill development, Professional ethics and teamwork, Technical report preparation |
| 232EEPE086 | Project Phase I | Project | 6 | Detailed literature survey, Problem definition and scope finalization, Methodology selection and design, Preliminary experimental setup/simulation design, Mid-term progress reporting |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 232EEPE087 | Project Phase II | Project | 10 | Project implementation and execution, Data collection and analysis, Result validation and interpretation, Comprehensive thesis writing, Project defense and viva-voce |
