2014 IEEE Power Electronics Projects for MTech


CodeProject TitleAbstract
AT14-01A Modified Three-Phase Four-Wire UPQC Topology With Reduced DC-Link Voltage RatingDownload
AT14-02FPGA-Based Predictive Sliding Mode Controller of a Three-Phase InverterDownload
AT14-03Pulsewidth Modulation of Z-Source Inverters With Minimum Inductor Current RippleDownload
AT14-04Improving the Dynamics of Virtual-Flux-Based Control of Three-Phase Active RectifiersDownload
AT14-05Sensorless Induction Motor Drive Using Indirect Vector Controller and Sliding-Mode Observer for
Electric Vehicles
AT14-06Back-Propagation Control Algorithm for Power Quality Improvement Using DSTATCOMDownload
AT14-07A Zero-Voltage Switching Three-Phase InverterDownload
AT14-08Control of Reduced-Rating Dynamic Voltage Restorer With a Battery Energy Storage SystemDownload
AT14-09A Combination of Shunt Hybrid Power Filter and Thyristor-Controlled Reactor for Power QualityDownload
AT14-10A Transformerless Grid-Connected Photovoltaic System Based on the Coupled Inductor Single-Stage Boost Three-Phase InverterDownload
AT14-11LCL Filter Design and Performance Analysis for Grid-Interconnected SystemsDownload
AT14-12An Inductively Active Filtering Method for Power-Quality Improvement of Distribution Networks With Nonlinear LoadsDownload
AT14-13A Bidirectional-Switch-Based Wide-Input Range High-Efficiency Isolated Resonant Converter for Photovoltaic ApplicationsDownload
AT14-14Analysis and Implementation of an Improved Flyback Inverter for Photovoltaic AC Module ApplicationsDownload
AT14-15Speed Sensorless Vector Controlled Induction Motor Drive Using Single Current SensorDownload
AT14-16A Novel Design and Optimization Method of an LCL Filter for a Shunt Active Power FilterDownload
AT14-17An Active Harmonic Filter Based on One-Cycle ControlDownload
AT14-18A Nine-Level Grid-Connected Converter Topology for Single-Phase Transformerless PV Systems
AT14-19Modeling and Design of Voltage Support Control
Schemes for Three-Phase Inverters Operating Under Unbalanced Grid Conditions
AT14-20Cascaded Two-Level Inverter-Based Multilevel STATCOM for High-Power Applications
AT14-21A Voltage-Controlled DSTATCOM for Power-Quality Improvement
AT14-22Solar PV and Battery Storage Integration using a New Configuration of a Three-Level NPC Inverter With Advanced Control Strategy
AT14-23A Current Control MPPT Method in High Power Solar Energy Conversion System
AT14-24A Novel Five-Level Inverter for Solar System
AT14-25A Single-Stage Three-Phase Grid-Connected Photo-Voltaic System With Fractional Order MPPT
AT14-26Design and Implementation of Sliding Mode and PI Controllers
based Control for Three Phase Shunt Active Power Filter
AT14-27Implementation of Adaptive Filter in
Distribution Static Compensator
AT14-28A Comparison of Soft-Switched DC-to-DC Converters for Electrolyzer Application
AT14-29Adaptive fuzzy controller based MPPT for photovoltaic systems
AT14-30Design of Fuzzy Logic Based Maximum Power Point Tracking Controller for Solar Array for Cloudy Weather onditions.
AT14-31Dynamic Behavior of DFIG Wind Turbine Under Grid Fault Conditions
AT14-32Fuzzy-Logic-Controller-Based SEPIC Converter for Maximum Power Point Tracking
AT14-33Performance Improvement of Direct Power Control of PWM Rectifier With Simple Calculation
AT14-34FLC-Based DTC Scheme to Improve the Dynamic Performance of an IM Drive
AT14-35Single Phase Grid-Connected Photovoltaic Inverter for Residential Application with Maximum Power Point Tracking
AT14-36Improved Active Power Filter Performance for Renewable Power Generation Systems
AT14-37Micro Wind Power Generator with Battery Energy Storage for Critical Load

The table lists the latest Power Electronics Projects

Power Electronics is the study of switching electronic circuits in order to control the flow of electrical energy. Power Electronics is the technology behind switching power supplies, power converters, power inverters, motor drives, and motor soft starters.

Power electronics is one of the contemporary subjects of electrical engineering which has seen a lot of advancements in recent times and has impacted human life in almost every sphere. We over selves use so many power electronic applications in our daily life, without even realizing it. Now the question stands as, “what is power electronics?”
We can define power electronics as a subject which is a hybrid of power engineering, analogue electronics, semiconductor devices and control systems. We derive the fundamentals of each subject and apply it in an amalgamated way so as to get a regulated form of electrical energy. Electrical energy in itself is not usable until it is converted into a tangible form of energy such as motion, light, sound, heat etc. In order to regulate these forms of energy, an effective way is to regulate the electrical energy itself and this forms the content of the subject power electronics.