# 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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**2019 IEEE POWER ELECTRONICS TITLES**

### Standard Electrical Units of Measure

Electrical Parameter |
Measuring Unit |
Symbol | Description |

Voltage | Volt | V or E | Unit of Electrical PotentialV = I × R |

Current | Ampere | I or i | Unit of Electrical CurrentI = V ÷ R |

Resistance | Ohm | R or Ω | Unit of DC ResistanceR = V ÷ I |

Conductance | Siemen | G or ℧ | Reciprocal of ResistanceG = 1 ÷ R |

Capacitance | Farad | C | Unit of CapacitanceC = Q ÷ V |

Charge | Coulomb | Q | Unit of Electrical ChargeQ = C × V |

Inductance | Henry | L or H | Unit of InductanceV_{L} = -L(di/dt) |

Power | Watts | W | Unit of PowerP = V × I or I^{2} × R |

Impedance | Ohm | Z | Unit of AC ResistanceZ^{2} = R^{2} + X^{2} |

Frequency | Hertz | Hz | Unit of Frequencyƒ = 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.

## 2019 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.