Power Electronics Projects
Power electronics finds applications in Control of AC & DC drives in industries, commercial, aerospace, utility and military applications and also it plays an important role in switching power supplies, High voltage DC lines which interconnect two different AC systems. Rapid developments in recent times indicate the applications of semiconductor power devices that can efficiently switch large current at high voltages with an emphasis on low power loss.
Projectsinbangalore Offers IEEE Based Power electronics Projects for Final Year BE, Btech, Mtech Engineering Students.Matlab and Simulink based Projects are available for EEE Students.
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1. A Cascaded H-Bridge With Integrated Boosting Circuit
2. A Converter-Level on-State Voltage Measurement Method for Power Semiconductor Devices
3. A Coupling Mechanism With Multi degree Freedom for Bidirectional Multistage WPT System
4. A Digital Twin Based Estimation Method for Health Indicators of DC–DC Converters
5. A Distributed Control Strategy for Parallel DC-DC Converters
6. A Fault Diagnosis and Post fault Reconfiguration Scheme for Interleaved Boost Converter in PV-Based System
7. A High Step-Up Switched-Capacitor 13-Level Inverter With Reduced Number of Switches
8. A Hybrid Binary-Cascaded Multilevel Inverter With Simple Floating-Capacitor-Voltage Control
9. A Hybrid, Fully-Integrated, Dual-Output DC–DC Converter for Portable Electronics
10. A Multiport DC–DC Converter Based on Two-Quadrant Inverter Topology for PV Systems
11. A New Seven-Level Topology for High-Power Medium-Voltage Application
12. A New Simple-Structure Passive Lossless Snubber for DC–DC Boost Converters
13. A Novel High Step-Up Switched-Capacitor Multilevel Inverter With Self-Voltage Balancing
14. A Novel Modified Switched Inductor Boost Converter With Reduced Switch Voltage Stress
15. A Novel Three-Level CLLC Resonant DC–DC Converter for Bidirectional EV Charger in DC Microgrids
16. A Reduced Series/Parallel Module for Cascade Multilevel Static Compensators Supporting Sensorless Balancing
17. A Six-Switch Seven-Level Triple-Boost Inverter
18. A Step-Up Multilevel Inverter Topology Using Novel Switched Capacitor Converters With Reduced Components
19. An Efficient Three-Phase Resonant DC-Link Inverter With Low Energy Consumption
20. An Interlinking Converter for Renewable Energy Integration Into Hybrid Grids
21. Analysis and Utilization of the Frequency Splitting Phenomenon in Wireless Power Transfer Systems
22. Bidirectional DC–DC Wireless Power Transfer Based on LCC-C Resonant Compensation
23. DC Capacitor-Less Solid-State Variable Capacitor
24. DC Current Control for a Single-Stage Current Source Inverter in Motor Drive Application
25. Design and Optimization of an Electric Vehicle Wireless Charging System Using InterleavedBoost Converter and Flat Solenoid Coupler
26. Design of an Isolated Bidirectional DC–DC Converter With Built-in Filters for High Power Density
27. Direct AC–AC Active-Clamped Half-Bridge Converter for Inductive Charging Applications
28. Double Half-Bridge Submodule-Based Modular Multilevel Converters With Reduced Voltage Sensors
29. Extended Range Bridgeless PFC Converter With High-Voltage DC Bus and Small Inductor
30. Fault Detection in a Hybrid Dickson DC–DC Converter for 48-V Automotive Applications
Standard Electrical Units of Measure
| Electrical Parameter |
Measuring Unit |
Symbol | Description |
| Voltage | Volt | V or E | Unit of Electrical Potential V = I × R |
| Current | Ampere | I or i | Unit of Electrical Current I = V ÷ R |
| Resistance | Ohm | R or Ω | Unit of DC Resistance R = V ÷ I |
| Conductance | Siemen | G or ℧ | Reciprocal of Resistance G = 1 ÷ R |
| Capacitance | Farad | C | Unit of Capacitance C = Q ÷ V |
| Charge | Coulomb | Q | Unit of Electrical Charge Q = C × V |
| Inductance | Henry | L or H | Unit of Inductance VL = -L(di/dt) |
| Power | Watts | W | Unit of Power P = V × I or I2 × R |
| Impedance | Ohm | Z | Unit of AC Resistance Z2 = R2 + X2 |
| Frequency | Hertz | Hz | Unit of Frequency ƒ = 1 ÷ T |
Multiples and Sub-multiples
There is a huge range of values encountered in electrical projects and electronic engineering projects between a maximum value and a minimum value of a standard electrical unit. For example, resistance can be lower than 0.01Ω or higher than 1,000,000Ω. By using multiples and submultiple’s of the standard unit we can avoid having to write too many zero’s to define the position of the decimal point. The table below gives their names and abbreviations.
2026 IEEE POWER ELCTRNICS TOPICS
- A Novel Reduced Switching Loss Bidirectional AC/DC Converter PWM Strategy with Feed-Forward Control for Grid-Tied Micro Grid Systems
- Analysis, Design, and Performance Evaluation of Droop Current-Sharing Method
- High Voltage-Boosting Converters Based on Bootstrap Capacitors and Boost Inductors
- Integration and Operation of a Single-Phase Bidirectional Inverter With Two Buck/Boost MPPTs for DC-Distribution Applications
- A 1.65 W Fully Integrated 90 nm Bulk CMOS Capacitive DC-DC Converter With Intrinsic Charge Recycling.
- A Comparison of Soft-Switched DC-to-DC Converters for Electrolyzer Application.
- A High-Efficiency Solar Array Simulator Implemented by an LLC Resonant DC-DC Converter.
- An Advanced Power Electronics Interface for Electric Vehicles Applications.
- Control Strategy for Power Flow Management in a PV System Supplying DC Loads.
- High Boost Ratio Hybrid Transformer DC-DC Converter for Photovoltaic Module Applications.