MTech Power Electronics Projects – Complete Guide for Final Year Students (2026)

Selecting the right MTech Power Electronics project is a crucial step for final year students. Power Electronics is one of the most practical and application-driven domains in electrical engineering, where concepts are directly applied in real-world systems such as electric vehicles, renewable energy, and industrial automation.

Unlike basic engineering projects, MTech-level projects require deeper understanding of converter design, control strategies, switching techniques, and system integration. Many students struggle not because the subject is difficult, but because they choose topics without considering feasibility, tools, and implementation scope.

A well-planned project helps in better understanding, smoother execution, and stronger performance during evaluation and viva.

MTech Power Electronics Projects for Final Year Students (2026)

1. Design and Implementation of a Bidirectional DC-DC Converter for Electric Vehicle Charging Applications
2. Development of a Grid-Connected Solar Inverter with Maximum Power Point Tracking and Power Quality Improvement
3. Design and Analysis of a Cascaded H-Bridge Multilevel Inverter for Harmonic Reduction in Power Systems
4. Implementation of a Wireless Power Transfer System for Electric Vehicle Battery Charging
5. Design of a High Gain DC-DC Boost Converter for Renewable Energy Applications
6. Development of a Modular Multilevel Converter for High Voltage DC Transmission Systems
7. Design and Control of an Active Power Filter for Harmonic Mitigation in Industrial Loads
8. Implementation of a Fuzzy Logic Based Control for a DC-DC Converter in Renewable Energy Systems
9. Design of a Soft Switching Resonant Converter for High Efficiency Power Conversion
10. Development of a Vehicle-to-Grid (V2G) Power Converter System for Smart Grid Applications

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11. Design and Implementation of an Interleaved DC-DC Converter for High Power Applications
12. Development of a Switched Capacitor Multilevel Inverter with Reduced Switch Count
13. Design of a STATCOM Based Power Quality Improvement System for Distribution Networks
14. Implementation of Model Predictive Control for a Grid-Connected Voltage Source Inverter
15. Design and Development of a Multiport DC-DC Converter for Hybrid Energy Systems
16. Development of a Single-Phase Grid-Connected Inverter with LCL Filter for Harmonic Reduction
17. Design of a Three-Phase Voltage Source Inverter for Motor Drive Applications
18. Implementation of a Neural Network Based Control for DC-DC Converters
19. Design and Analysis of a Quasi-Z Source Inverter for Renewable Energy Systems
20. Development of a Hybrid Multilevel Inverter for Electric Vehicle Applications

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21. Design and Implementation of a Power Factor Correction Converter for Industrial Loads
22. Development of a Dynamic Voltage Restorer for Voltage Sag and Swell Compensation
23. Design of a Battery Energy Storage System with Bidirectional Converter for Microgrid Applications
24. Implementation of Sliding Mode Control for DC-DC Converter Systems
25. Design and Development of a High Frequency Transformer Based DC-DC Converter
26. Development of a Grid-Interactive Inverter for Distributed Generation Systems
27. Design of a Three-Level Neutral Point Clamped Inverter for Medium Voltage Applications
28. Implementation of Space Vector PWM Technique for Multilevel Inverter Control
29. Design and Analysis of a Hybrid Renewable Energy System with Power Electronic Interface
30. Development of a Soft Switching Full Bridge Converter with Zero Voltage Switching

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31. Design and Implementation of a Power Electronic Transformer for Smart Grid Applications
32. Development of a DC Microgrid with Integrated Power Electronic Converters
33. Design of a Fault Tolerant Multilevel Inverter for Critical Applications
34. Implementation of an IoT-Based Monitoring System for Power Electronic Converters
35. Design and Development of a High Efficiency LED Driver Using DC-DC Converter
36. Development of a Multi-Level Converter for STATCOM Applications
37. Design of a Resonant Converter for Wireless Charging Applications
38. Implementation of Adaptive Control Techniques for Power Electronic Systems
39. Design and Development of a Grid Connected Hybrid Inverter for Solar PV Systems
40. Development of a High Power Density DC-DC Converter for Electric Vehicle Applications

41. Design and Implementation of a Dual Active Bridge (DAB) Converter for Bidirectional Power Transfer Applications
42. Development of a SiC-Based High Efficiency Power Converter for Electric Vehicle Applications
43. Design and Analysis of a Multilevel Inverter with Reduced Total Harmonic Distortion Using Advanced PWM Techniques
44. Implementation of a Digital Control Strategy for High Frequency DC-DC Converters Using DSP
45. Development of a Hybrid Energy Storage Interface Converter for Renewable Energy Systems
46. Design of a Three-Phase Vienna Rectifier for Power Factor Correction in Industrial Applications
47. Implementation of a Predictive Current Control for Grid-Connected Inverters
48. Development of a High Frequency Isolated DC-DC Converter for Telecom Power Supplies
49. Design and Implementation of a Modular Multilevel Converter for Battery Energy Storage Systems
50. Development of a Soft Switching Interleaved Boost Converter for High Power Renewable Applications

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Trending Technologies in Power Electronics (2026)

Power Electronics is rapidly evolving with new technologies and applications. Some of the most trending areas include:

• Electric vehicle power systems and charging infrastructure
• Wide bandgap devices such as SiC and GaN converters
• Smart grid and grid-connected inverter systems
• High efficiency and soft switching converter designs
• AI-based control techniques for power converters

Working on these areas increases the chances of better academic performance, research publication, and industry relevance.

Why Students Need Guidance for MTech Power Electronics Projects

MTech projects involve multiple stages including design, simulation, hardware implementation, and testing. Students often face challenges such as:

• Difficulty in selecting the right topic
• Lack of clarity in converter design and control strategies
• Issues in simulation and hardware integration
• Time constraints before submission

Proper guidance helps in structured execution, better understanding, and timely completion of the project.

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Conclusion

Choosing the right MTech Power Electronics project is about clarity, practicality, and proper execution. A well-planned project that you understand and can implement effectively will always give better results than a complex one. By focusing on the right domain and approach, you can complete your project smoothly and perform confidently during evaluation.