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M-TECH in Power Electronics And Drives at B. S. Abdur Rahman Crescent Institute of Science and Technology
Chengalpattu, Tamil Nadu
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About the Specialization
What is Power Electronics and Drives at B. S. Abdur Rahman Crescent Institute of Science and Technology Chengalpattu?
This Power Electronics and Drives M.Tech program at B.S. Abdur Rahman Crescent Institute of Science and Technology focuses on equipping students with advanced knowledge and skills in the design, control, and application of power electronic converters and electrical drives. It addresses the growing demand for efficient energy conversion, motor control, and integration of renewable energy sources in the Indian industry. The program emphasizes both theoretical foundations and practical applications, preparing graduates for cutting-edge roles.
Who Should Apply?
This program is ideal for electrical and electronics engineering graduates seeking to specialize in the rapidly evolving fields of power electronics, electric drives, and renewable energy. It attracts fresh graduates aspiring to contribute to India''''s energy and manufacturing sectors, as well as working professionals looking to upskill in areas like electric vehicles, smart grids, and industrial automation. Students with a strong foundation in circuit theory and control systems are particularly well-suited.
Why Choose This Course?
Graduates of this program can expect to pursue rewarding careers in India''''s power sector, automotive industry (EVs), renewable energy companies, and manufacturing automation firms. Roles include R&D engineer, power electronics design engineer, drive control specialist, and system integration engineer. Entry-level salaries typically range from INR 4-7 LPA, with experienced professionals earning significantly higher. The specialized skills gained align with industry certifications in areas like embedded control and power converter design, boosting career growth.
Student Success Practices
Foundation Stage
Strengthen Core Concepts & Analytical Skills- (Semester 1-2)
Dedicate time to master the fundamental principles of power electronics, electrical machines, and control systems from the first semester. Utilize online platforms for practice problems and engage in group discussions. Develop strong mathematical and analytical skills through regular problem-solving.
Tools & Resources
NPTEL courses, MIT OpenCourseware, MATLAB/Simulink tutorials, Peer study groups
Career Connection
A solid foundation is crucial for understanding advanced topics and performing well in technical interviews for R&D and design roles.
Hands-on Lab Competency & Simulation Proficiency- (Semester 1-2)
Actively participate in all laboratory sessions, striving for a deep understanding of experimental procedures and data analysis. Complement practical work with extensive simulation using industry-standard software to model and analyze power electronic circuits and drive systems.
Tools & Resources
Power Electronics Lab equipment, PSpice, PSIM, Plecs, MATLAB/Simulink
Career Connection
Practical skills and simulation expertise are highly valued by employers for design, development, and testing positions in power electronics companies.
Explore Research Papers & Emerging Trends- (Semester 1-2)
Start early by exploring current research papers in power electronics, electric drives, and related fields like renewable energy or electric vehicles. Attend departmental seminars and workshops to stay updated on emerging technologies and identify potential research interests.
Tools & Resources
IEEE Xplore, Google Scholar, ResearchGate, Departmental seminar series
Career Connection
Early exposure to research helps in identifying relevant project topics, fosters critical thinking, and prepares for advanced R&D careers.
Intermediate Stage
Undertake Mini-Projects & Technical Competitions- (Semester 2-3)
Actively engage in mini-projects, either individually or in teams, focusing on designing and implementing power electronic converters or drive control systems. Participate in national-level technical competitions to showcase skills and gain practical experience.
Tools & Resources
Microcontrollers (e.g., Arduino, STM32), DSP boards (e.g., dsPIC), Component suppliers (e.g., Mouser, RS Components), IEEE student competitions
Career Connection
Practical project experience demonstrates problem-solving abilities and technical application, making candidates more attractive for internships and entry-level engineering roles.
Network with Industry Professionals & Alumni- (Semester 2-3)
Attend industry conferences, tech talks, and career fairs to connect with professionals working in power electronics and drives. Leverage the institute''''s alumni network for mentorship, insights, and potential internship leads.
Tools & Resources
LinkedIn, Professional body events (e.g., IEEE PELS/IAS chapter events), Alumni association portals
Career Connection
Networking opens doors to internship opportunities, industry insights, and future job prospects in core engineering sectors.
Develop Programming & Embedded System Skills- (Semester 2-3)
Beyond theoretical control, gain proficiency in programming languages like C/C++ for embedded systems and Python for data analysis and machine learning applications in power electronics. Understand real-time operating systems relevant to control applications.
Tools & Resources
C/C++ compilers, Python programming tutorials, Microcontroller development environments (IDE), Online coding platforms
Career Connection
Strong programming skills are essential for implementing digital control algorithms, developing firmware, and working with smart control systems in modern power electronic applications.
Advanced Stage
Intensive Project Work & Publication Focus- (Semester 3-4)
Commit thoroughly to the project work, aiming for an innovative solution with tangible results. Strive to publish research findings in reputable conferences or journals, enhancing academic and professional credentials. Focus on deep-diving into a niche area.
Tools & Resources
Research labs, University library resources, Scopus, Web of Science, Technical writing guides
Career Connection
A well-executed project, especially with a publication, significantly boosts employability for R&D roles and provides a strong foundation for future doctoral studies.
Targeted Internship & Industry Training- (Semester 3-4)
Seek out relevant internships in companies specializing in power electronics, electric vehicles, or industrial drives during semester breaks or as part of the curriculum. Gain practical industry experience and understand corporate workflows.
Tools & Resources
College placement cell, Company career pages, Internshala, LinkedIn Jobs
Career Connection
Internships are critical for gaining industry exposure, building professional networks, and often lead to pre-placement offers, streamlining the job search process.
Refine Interview Skills & Placement Preparation- (Semester 4)
Participate in mock interviews, aptitude test preparations, and resume building workshops organized by the placement cell. Focus on behavioral and technical questions specific to power electronics and drives roles.
Tools & Resources
Placement cell resources, Online aptitude tests, Technical interview prep books/websites (e.g., GeeksforGeeks, InterviewBit)
Career Connection
Thorough preparation for placement interviews is essential to convert technical expertise into successful job offers from top companies in the sector.
Program Structure and Curriculum
Eligibility:
- B.E./B.Tech. (EEE/EIE/ECE/ICE/Instrumentation & Control) with minimum 50% marks in the qualifying examination. A valid GATE score or entrance examination score conducted by the institution is generally required.
Duration: 2 years / 4 semesters
Credits: 73 Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAP2101 | Applied Mathematics for Electrical Engineering | Core | 4 | Linear Algebra, Numerical Methods, Transform Techniques, Partial Differential Equations, Probability and Statistics |
| MPD2101 | Analysis of Power Converters | Core | 4 | AC-DC Converters (Rectifiers), DC-DC Converters (Choppers), DC-AC Converters (Inverters), PWM Techniques, Multilevel Inverters |
| MPD2102 | Advanced Control of Electrical Drives | Core | 4 | Mathematical Modeling of AC Machines, Vector Control of Induction Motor, Direct Torque Control, Sensorless Control, Observer Design |
| MPD2103 | Power Semiconductor Devices and Reliability | Core | 4 | Power Diodes and Thyristors, MOSFETs and IGBTs, Wide Bandgap Devices (SiC, GaN), Gate Driver Circuits, Thermal Management and Reliability |
| MPD2104 | Power Electronics and Drives Laboratory I | Lab | 2 | Static Converter Experiments, DC-DC Chopper Circuits, Inverter Operation, Motor Control Basics, Simulation Tools (e.g., MATLAB/Simulink) |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MPD2201 | Electric Drives and Control | Core | 4 | DC Motor Drives, Induction Motor Drives, Synchronous Motor Drives, Special Machine Drives, Field Oriented Control |
| MPD2202 | Digital Control of Power Electronic Converters | Core | 4 | Digital Control Principles, DSP and Microcontroller Applications, Digital PWM Generation, Real-time Control Implementation, FPGA based Control |
| MPD2203 | Advanced Power System Stability and Control | Core | 4 | Power System Dynamics, Voltage Stability Analysis, Transient Stability Enhancement, FACTS Devices for Stability, Wide Area Monitoring |
| MPDE2101 | Renewable Energy Systems and Grid Integration | Elective | 3 | Solar Photovoltaic Systems, Wind Energy Conversion Systems, Hybrid Renewable Energy Systems, Grid Interconnection Challenges, Energy Storage Systems |
| MPD2204 | Power Electronics and Drives Laboratory II | Lab | 2 | Advanced Converter Control, Sensorless Vector Control, DSP-based Drive Experiments, Battery Management Systems, Hardware-in-Loop Simulations |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MPD2301 | Research Methodology and IPR | Core | 3 | Research Problem Formulation, Research Design and Methods, Statistical Data Analysis, Technical Report Writing, Intellectual Property Rights |
| MPDE2102 | Switched Mode Power Supplies | Elective | 3 | DC-DC Converter Topologies, Flyback and Forward Converters, Resonant Converters, Power Factor Correction, Control of SMPS |
| MPDE2103 | Electric Vehicles and Charging Infrastructure | Elective | 3 | EV Architectures and Components, Battery Technologies and BMS, Motor Drives for EVs, EV Charging Technologies, Grid Integration of EVs |
| MPD2302 | Project Work Phase I | Project | 6 | Literature Survey, Problem Identification and Formulation, System Design and Methodology, Simulation Studies, Project Proposal and Presentation |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MPD2401 | Project Work Phase II | Project | 18 | Prototype Development, Experimental Validation and Analysis, Performance Evaluation, Thesis Writing and Documentation, Final Project Defense |
