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Power Electronics IEEE Projects 2017-2018
Power Electronics IEEE Projects 2017-2018, Power Electronics IEEE Projects Titles 2017-2018. We are offering ieee projects 2017-2018 in latest technology like Java ieee projects, dotnet ieee projects, android ieee projects, embedded ieee projects, matlab ieee projects, digital image processing ieee projects, dip ieee projects, vlsi ieee projects, hadoop ieee projects, big data ieee projects, power electronics ieee projects, power system ieee projects, diploma embedded projects, embedded mini projects, mechanical projects, diploma mechanical projects, civil projects ieee projects. IEEE Master is a unit of LeMeniz Infotech. We guide all final year M.E/M.Tech, B.E/B.Tech, MPhil, MCA, BCA, M.Sc, B.Sc, and Diploma students for their Academic Projects to get best results. Download latest Power Electronics IEEE Projects Titles 2017-2018
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| S.No | Code | IEEE Based on SOLAR ENERGY | Year |
|---|
| 1 | LM_PE_SE017_01 | Nonlinear PWM-Controlled Single-Phase Boost Mode Grid- Connected Photovoltaic Inverter With Limited Storage Inductance Current | 2017 |
| 2 | LM_PE_SE017_02 | A Family of Neutral-Point-Clamped Circuits of Single-Phase PV Inverters Generalized Principle and Implementation | 2017 |
| 3 | LM_PE_SE017_03 | A New Six-Switch Five-Level Active Neutral Point Clamped Inverter for PV Applications | 2017 |
| 4 | LM_PE_SE017_04 | Single-Stage Three-Phase Current-Source Photovoltaic Grid- Connected Inverter High Voltage Transmission Ratio | 2017 |
| 5 | LM_PE_SE017_05 | A Highly Efficient and Reliable Inverter Configuration Based Cascaded Multilevel Inverter for PV Systems | 2017 |
| 6 | LM_PE_SE017_06 | Modified Single-Phase Single-Stage Grid-tied Flying Inductor Inverter with MPPT and Suppressed Leakage Current | 2017 |
| 7 | LM_PE_SE017_07 | A Multilevel Transformer less Inverter employing Ground
Connection between PV Negative Terminal and Grid Neutral
Point | 2017 |
| 8 | LM_PE_SE017_08 | An Improved Zero-Current-Switching Single-Phase Transformer less PV H6 Inverter with Switching Loss-Free | 2017 |
| 9 | LM_PE_SE017_09 | Modulation Technique for Single-Phase Transformer less
Photovoltaic Inverters with Reactive Power Capability | 2017 |
| | | |
| S.No | Code | IEEE Based on WIND ENERGY | Year |
|---|
| 1 | LM_PE_WI017_01 | A Medium-Frequency Transformer-Based Wind Energy Conversion System Used for Current-Source Converter-Based Offshore Wind Farm | 2017 |
| 2 | LM_PE_WI017_02 | Replacing the Grid Interface Transformer in Wind Energy Conversion System With Solid-State Transformer | 2017 |
| 3 | LM_PE_WI017_03 | Bipolar Operation Investigation of Current Source Converter-Based Wind Energy Conversion Systems | 2017 |
| 4 | LM_PE_WI017_04 | Control Strategy of Wind Turbine Based on Permanent Magnet Synchronous Generator and Energy Storage for Stand-Alone Systems | 2017 |
| 5 | LM_PE_WI017_05 | Novel Isolated Power Conditioning Unit for Micro Wind Turbine Application | 2017 |
| S.No | Code | IEEE Based on MICROGRID | Year |
|---|
| 1 | LM_PE_MG017_01 | Bidirectional Single-Stage Grid-Connected Inverter for a
Battery Energy Storage System | 2017 |
| 2 | LM_PE_MG107_02 | Electric Vehicle Charging Station With an Energy Storage Stage for Split-DC Bus Voltage Balancing | 2017 |
| 3 | LM_PE_MG017_03 | A Decentralized Dynamic Power Sharing Strategy for Hybrid Energy Storage System in Autonomous DC Microgrid | 2017 |
| 4 | LM_PE_MG017_04 | Control of a Hybrid AC/DC Microgrid Involving Energy Storage and Pulsed Load | 2017 |
| 5 | LM_PE_MG017_05 | Hybrid Energy Storage System Micro Grids Integration For
Power Quality Improvement Using Four Leg Three Level
NPC Inverter and Second Order Sliding Mode Control | 2017 |
| S.No | Code | IEEE Based on MULTIPORT | Year |
|---|
| 1 | LM_PE_MP017_01 | Secondary-Side-Regulated Soft-Switching Full-Bridge Three-Port Converter Based on Bridgeless Boost Rectifier and Bidirectional Converter for Multiple Energy Interface | 2017 |
| 2 | LM_PE_MP107_02 | Analysis, Design, Modelling, and Control of an Interleaved- Boost Full-Bridge Three-Port Converter for Hybrid Renewable Energy Systems | 2017 |
| 3 | LM_PE_MP017_03 | Design and Implementation of an Amorphous High- Frequency Transformer Coupling Multiple Converters in a Smart Micro grid | 2017 |
| 4 | LM_PE_MP017_04 | Dual-DC-Port Asymmetrical Multilevel Inverters With Reduced Conversion Stages and Enhanced Conversion Efficiency | 2017 |
| S.No | Code | IEEE Based on INVERTER | Year |
|---|
| 1 | LM_PE_IV017_01 | A Highly Reliable and High-Efficiency Quasi Single-Stage
Buck–Boost Inverter | 2017 |
| 2 | LM_PE_IV107_02 | A Four-Switch Single-Stage Single-Phase Buck–Boost Inverter | 2017 |
| 3 | LM_PE_IV017_03 | Interleaved Resonant Boost Inverter Featuring SiC Module
for High Performance Induction Heating | 2017 |
| 4 | LM_PE_IV017_04 | Modelling and Optimization of a Zero-Voltage Switching Inverter for High Efficiency and Miniaturization | 2017 |
| 5 | LM_PE_IV017_05 | Maximum Boost Control of Diode-Assisted Buck–Boost
Voltage-Source Inverter With Minimum Switching Frequency | 2017 |
| S.No | Code | IEEE Based on MULTI LEVEL AND ZSOURCE INVERTER | Year |
|---|
| 1 | LM_PE_ML017_01 | A Novel Nine-Level Inverter Employing One Voltage Source
and Reduced Components as High-Frequency AC Power
Source | 2017 |
| 2 | LM_PE_ML107_02 | Quasi Cascaded H-Bridge Five-Level Boost Inverter | 2017 |
| 3 | LM_PE_ML017_03 | Steady-State Analysis and Design Considerations of High
Voltage Gain Switched Z-Source Inverter With Continuous
Input Current | 2017 |
| 4 | LM_PE_ML017_04 | A New Class of Single-Phase High-Frequency Isolated ZSource AC-AC Converters with Reduced Passive Components | 2017 |
| 5 | LM_PE_ML017_05 | Enhanced-Boost Quasi-Z-Source Inverters with Two
Switched Impedance Network | 2017 |
| 6 | LM_PE_ML017_06 | High-Voltage Gain Half-Bridge Z-Source Inverter With Low-Voltage Stress on Capacitors | 2017 |
| S.No | Code | IEEE Based on DRIVES | Year |
|---|
| 1 | LM_PE_DR017_01 | A Novel Method of Reducing Commutation Torque Ripple for Brushless DC Motor Based on Cuk Converter | 2017 |
| 2 | LM_PE_DR017_02 | Design and Demonstration of High Power Density Inverter
for Aircraft Applicationsr | 2017 |
| 3 | LM_PE_DR017_03 | Commutation Torque Ripple Reduction in BLDC Motor Using Modified SEPIC converter and three-level NPC inverter | 2017 |
| 4 | LM_PE_DR017_04 | Quasi-Z-Source Indirect Matrix Converter Fed Induction
Motor Drive for Flow Control of Dye in Paper Mill | 2017 |
| S.No | Code | IEEE Based on WIRELESS POWER TRANSFER | Year |
|---|
| 1 | LM_PE_WL017_01 | Z-Source Resonant Converter With Constant Frequency and Load Regulation for EV Wireless Charger | 2017 |
| 2 | LM_PE_WL017_02 | Bidirectional Current-Fed Half-Bridge Configuration for
Inductive Wireless Power Transfer System | 2017 |
| 3 | LM_PE_WL017_03 | Steady-State Analysis and Design Considerations of High
Voltage Gain Switched Z-Source Inverter With Continuous
Input Current | 2017 |
| 4 | LM_PE_WL017_04 | Higher Order Compensation for Inductive-Power-Transfer Converters With Constant-Voltage or Constant-Current
Output Combating Transformer Parameter Constraints | 2017 |
| 5 | LM_PE_WL017_05 | Enhanced-Boost Quasi-Z-Source Inverters with Two
Switched Impedance Network | 2017 |
| 6 | LM_PE_WL017_06 | Simultaneous Wireless Power Transfer for Electric Vehicle Charging | 2017 |
| S.No | Code | IEEE Based on CONVERTERS: BUCKBOOST, SEPIC,FLYBACK,PUSHPULL | Year |
|---|
| 1 | LM_PE_CV017_01 | Design and Analysis of a Class of Zero Fundamental Ripple
Converters | 2017 |
| 2 | LM_PE_CV017_02 | Analysis and Design of Impulse-Commutated Zero-Current- Switching Single-Inductor Current-Fed Three-Phase Push– Pull Converter | 2017 |
| 3 | LM_PE_CV017_03 | A Cascaded Coupled Inductor-Reverse High Step-Up Converter Integrating Three-Winding Coupled Inductor and
Diode–Capacitor Technique | 2017 |
| 4 | LM_PE_CV017_04 | Passive Regenerative and Dissipative Snubber Cells for Isolated SEPIC Converters | 2017 |
| 5 | LM_PE_CV017_05 | A New Negative Output Buck-Boost Converter with Wide
Conversion Ratio | 2017 |
| 6 | LM_PE_CV017_06 | A Novel Structure for Single-Switch Non isolated Transformer less Buck–Boost DC–DC Converter | 2017 |
| 7 | LM_PE_CV017_07 | High-Efficiency Asymmetric Forward-Flyback Converter for
Wide Output Power Range | 2017 |
| S.No | Code | IEEE Based on HIGH –VOLTAGE | Year |
|---|
| 1 | LM_PE_HV017_01 | A High-Voltage-Gain DC–DC Converter Based on Modified Dickson Charge Pump Voltage Multiplier | 2017 |
| 2 | LM_PE_HV017_02 | Zero-Ripple Input-Current High-Step-Up Boost–SEPIC DC– DC Converter With Reduced Switch-Voltage Stress | 2017 |
| 3 | LM_PE_HV017_03 | Ultra large Gain Step-Up Coupled-Inductor DC–DC Converter With an Asymmetric Voltage Multiplier Network for a Sustainable Energy System | 2017 |
| 4 | LM_PE_HV017_04 | A High Step-up PWM DC-DC Converter With Coupled- Inductor and Resonant Switched-Capacitor | 2017 |
| 5 | LM_PE_HV017_05 | A High-Efficiency Step-Up Current-Fed Push–Pull Quasi-
Resonant Converter With Fewer Components for Fuel Cell
Application | 2017 |
| S.No | Code | IEEE Based on MULTIPLE OUTPUT CONVERTER | Year |
|---|
| 1 | LM_PE_MO017_01 | Design and Implementation of a High-Efficiency Multiple Output Charger Based on the Time-Division Multiple Control Technique | 2017 |
| 2 | LM_PE_MO017_02 | Zero-Ripple Input-Current High-Step-Up Boost–SEPIC DC– DC Converter With Reduced Switch-Voltage Stress | 2017 |
| 3 | LM_PE_HV017_03 | Ultra large Gain Step-Up Coupled-Inductor DC–DC Converter With an Asymmetric Voltage Multiplier Network for a Sustainable Energy System | 2017 |
| 4 | LM_PE_HV017_04 | A High Step-up PWM DC-DC Converter With Coupled- Inductor and Resonant Switched-Capacitor | 2017 |
| S.No | Code | IEEE Based on LED APPLICATIONS | Year |
|---|
| 1 | LM_PE_LE017_01 | An AC–DC LED Driver With a Two-Parallel Inverted Buck
Topology for Reducing the Light Flicker in Lighting Applications to Low-Risk Levels | 2017 |
| 2 | LM_PE_LE017_02 | Single-Stage Single-Switch Four-Output Resonant LED Driver With High Power Factor and Passive Current Balancing | 2017 |
| 3 | LM_PE_LE017_03 | Single-Switch Coupled-Inductor-Based Two-Channel LED
Driver With a Passive Regenerative Snubber | 2017 |
| 4 | LM_PE_LE017_04 | Analysis and Design of a Single-Stage Isolated AC–DC LED Driver With a Voltage Doubler Rectifier | 2017 |
| 5 | LM_PE_LE017_05 | Flyback-Based Three-Port Topologies for Electrolytic
Capacitor-Less LED Drivers | 2017 |
| S.No | Code | IEEE Based on POWER FACTOR CORRECTION | Year |
|---|
| 1 | LM_PE_PF017_01 | Flexible Mode Bridgeless Boost PFC Rectifier With High Efficiency Over a Wide Range of Input Voltage | 2017 |
| 2 | LM_PE_PF017_02 | A Family of Single-Phase Voltage-Doubler High-Power-
Factor SEPIC Rectifiers Operating in DCM | 2017 |
| 3 | LM_PE_PF017_03 | A Family of Single-Phase Hybrid Step-Down PFC Converters | 2017 |
| S.No | Code | IEEE Based on SOFT SWITCHING CONVERTER | Year |
|---|
| 1 | LM_PE_SS017_01 | A T-Type Isolated Zero Voltage Switching DC–DC
Converter With Capacitive Output | 2017 |
| 2 | LM_PE_SS017_02 | A Hybrid ZVZCS Dual-Transformer-Based Full-Bridge Converter Operating in DCM for MVDC Grids | 2017 |
| 3 | LM_PE_SS017_03 | A New ZVT Snubber Cell for PWM-PFC Boost Converter | 2017 |
| 4 | LM_PE_SS017_04 | High-Efficiency Soft-Switching AC–DC Converter With Single-Power-Conversion Method | 2017 |
| 5 | LM_PE_SS017_05 | Soft-Switching Dual-Fly back DC–DC Converter With
Improved Efficiency and Reduced Output Ripple Current | 2017 |
| S.No | Code | IEEE Based on RESONANT CONVERTER | Year |
|---|
| 1 | LM_PE_RC017_01 | Analysis and Design of SQR-Based High-Voltage LLC
Resonant DC–DC Converter | 2017 |
| 2 | LM_PE_RC017_02 | A New Dual-Bridge Series Resonant DC-DC Converter with Dual-Tank | 2017 |
| 3 | LM_PE_RC017_03 | A Quasi-Resonant Current-Fed Converter With Minimum
Switching Losses | 2017 |
| 4 | LM_PE_RC017_04 | Design and Steady-State Analysis of Parallel Resonant DC– DC Converter for High-Voltage Power Generator | 2017 |
| 5 | LM_PE_RC017_05 | Dual-Bridge LLC Resonant Converter With Fixed-Frequency
PWM Control for Wide Input Applications | 2017 |
| S.No | Code | IEEE Based on Z SOURCE CONVERTER | Year |
|---|
| 1 | LM_PE_RC017_01 | High-Performance Quasi-Z-Source Series Resonant DC–DC
Converter for Photovoltaic Module-Level Power Electronics
Applications | 2017 |
| 2 | LM_PE_RC017_02 | Load and Source Battery Simulator Based on Z-Source Rectifier | 2017 |
| 3 | LM_PE_RC017_03 | Wide Input-Voltage Range Boost Three-Level DC–DC
Converter With Quasi-Z Source for Fuel Cell Vehicles | 2017 |
| 4 | LM_PE_RC017_04 | Quasi-Z-Source Network-Based Hybrid Power Supply System for Aluminium Electrolysis Industry | 2017 |
| 5 | LM_PE_RC017_05 | Hybrid Z-Source Boost DC–DC Converters | 2017 |
| S.No | Code | IEEE Based on INTERLEAVED CONVERTER | Year |
|---|
| 1 | LM_PE_IC017_01 | Interleaved LLC Resonant Converter With Hybrid Rectifier
and Variable-Frequency Plus Phase-Shift control for Wide
Output Voltage Range Applications | 2017 |
| 2 | LM_PE_IC017_02 | Zero-Voltage-Transition Interleaved Boost Converter With an Auxiliary Coupled Inductor | 2017 |
| 3 | LM_PE_IC017_03 | A Novel Interleaved Non isolated Ultrahigh-Step-Up DC–DC
Converter With ZVS Performance | 2017 |
| 4 | LM_PE_IC017_04 | Discontinuous Current Mode Operation of Two-Phase Interleaved Boost Dc-dc Converter with Coupled-inductor | 2017 |
| 5 | LM_PE_IC017_05 | A Novel Soft-Switching Interleaved Coupled-Inductor Boost
Converter with Only Single Auxiliary Circuit | 2017 |
| S.No | Code | IEEE Based on BIDIRECTIONAL CONVERTER | Year |
|---|
| 1 | LM_PE_BD017_01 | Cascaded High-Voltage-Gain Bidirectional Switched-Capacitor DC–DC Converters for Distributed Energy Resources Applications | 2017 |
| 2 | LM_PE_BD017_02 | High Light-Load Efficiency Power Conversion Scheme Using Integrated Bidirectional Buck Converter for Paralleled Server Power Supplies | 2017 |
| 3 | LM_PE_BD017_03 | Soft switched Modulation Techniques for an Isolated Bidirectional DC-AC | 2017 |
| 4 | LM_PE_BD017_04 | A Family of True Zero Voltage Zero Current Switching Non isolated Bidirectional DC–DC Converter With Wide Soft Switching Range | 2017 |
| 5 | LM_PE_BD017_05 | Modelling and Analysis of Dual-Active-Bridge Isolated
Bidirectional DC/DC Converter to Minimize RMS Current
with Whole Operating Range | 2017 |
| 6 | LM_PE_BD017_06 | A Control Map for a Bidirectional PWM Plus Phase-Shift- Modulated Push-Pull DC-DC Converter | 2017 |
| 7 | LM_PE_BD017_07 | Interleaved Switched-Capacitor Bidirectional DC-DC
Converter with Wide Voltage-Gain Range for Energy Storage
Systems | 2017 |
| 8 | LM_PE_BD017_08 | A Novel Reversal Coupled Inductor High-Conversion-Ratio Bi-directional DC-DC Converter | 2017 |
Power Electronics IEEE Projects 2017-2018
Power Electronics IEEE Projects 2017-2018, Power Electronics IEEE Projects Titles 2017-2018 We are offering ieee projects 2017-2018 in latest technology like Java ieee projects, dot net ieee projects, android ieee projects, ns2 ieee projects, embedded ieee projects, matlab ieee projects, digital image processing ieee projects, vlsi ieee projects, hadoop ieee projects, power elctronics ieee projects, power system ieee projects, mechanical ieee projects, civil projects ieee project. We guide all final year M.E/M.Tech, B.E/B.Tech, MPhil, MCA, BCA, M.Sc, B.Sc, and Diploma students for their Academic Projects to get best results. We are offering java ieee projects in pondicherry. LeMeniz Infotech is a new class of software concern committed to catalyzing the competence and competitiveness of its clients by helping them succeed through the power of information technology. Driven by the credo that solutions are effective only when organizational needs are accurately ascertained and aptly addressed; LeMeniz Infotech looks upon itself as an integral part of its client’s organization. We have varied and extensive expertise in software development, web portal development, application software development, e-commerce website development, mobile application development, search engine optimization, bulk sms services, social media marketing, ieee projects guidance and more.
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Abstract
Introduction
Existing System
Disadvantages
Proposed System
Advantages
System Requirement
References
Power Point Presentation
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Abstract
Modules Description
System Architecture
Data Flow Diagram
Litreature Survey
Referece Papers
Power Point Presentation
[/single_tab][single_tab title=”Second Review” tab_id=”1447275592540-2-1″]
Sample Coding
Sample Screen Shots
Power Point Presentation
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Table Design
Screen Shot
Conclusiton
[/single_tab][single_tab title=”Final Review” tab_id=”1447275646182-4-6″]
Final Document
Complete Source Code
Project Execution Video
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