Power Electronics Simulation Projects

Power Electronics Simulation Projects is a crucial and trending domain among researchers, our experts and scholars, are fulfilled with wide areas for intensive research. Accompanied by short explanation and major issues, we provide impactful and promising 10 project ideas which encompass several research areas of power electronics simulation:

  1. DC-DC Converter Design for Renewable Energy Systems

Key Goals: For application in renewable energy systems such as wind turbines and solar panels, various kinds of DC-DC converters such as buck, boost and buck-boost are required to be modeled and simulated.

Significant Research Areas:

  • Particularly for low-input voltages, focus on dynamic efficiency.
  • Thermal management and power density are the main highlights of this research.
  • Considering the MPPT (Maximum Power Point Tracking), develop productive control tactics.

Research Challenges:

  • Over a broad spectrum of input voltages, it demands to attain high capability.
  • In high-power applications, heat deprivation must be handled efficiently.
  1. Simulation of Multilevel Inverters for Grid-Connected Applications

Key Goals: Our research primarily concentrates on capability enhancement and mitigation of harmonics. For the purpose of connecting renewable energy sources to the grid, multilevel inverters ought to be designed and simulated.

Significant Research Areas:

  • Investigate the several inverters topologies such as cascaded H-bridge, diode-clamped and flying capacitor.
  • Analysis of harmonics and reduction tactics should be explored.
  • Development of grid synchronization and power capacity has to be emphasized.

Research Challenges:

  • Among functionality, expenses and difficulties, we have to consider the performance compensations.
  • Depending on diverse scenarios, effective grid synthesization is supposed to be assured.
  1. Development of Power Factor Correction (PFC) Circuits

Key Goals: Regarding industrial purposes, enhance the capability of AC-DC converters by simulating and evaluating diverse algorithms of PFC (Power factor Correction).

Significant Research Areas:

  • Conduct an extensive research on boost, buck-boost and other mechanisms of PFC.
  • We should explore the different modes of continuous and discontinuous conduction.
  • On capability of the entire system and power capacity, analyze its critical implications.

Research Challenges:

  • For harmonic disruption, PFC circuits should be developed and examined, if it addresses the industry guidelines.
  • At different load scenarios, it demands to assure high capacity.
  1. Wireless Power Transfer for Electric Vehicles

Key Goals: Especially for electric vehicle charging, wireless power transfer systems need to be developed and simulated by us. The system’s capacity and range are the main focus of this research.

Significant Research Areas:

  • Carry out a detailed analysis on inductive and resonant wireless power transfer methods.
  • Design of magnetic field and coil models is meant to be examined.
  • Capacity analysis and power management should be investigated.

Research Challenges:

  • Beyond diverse distances, high capability must be accomplished.
  • Security considerations and electromagnetic interference have to be handled effectively.
  1. Modeling and Control of Electric Vehicle Motor Drives

Key Goals: Considering the electric vehicle motor drives, we have to create a simulation model. For better functionality and capability, it efficiently concentrates on control tactics.

Significant Research Areas:

  • Induction motors and PMSMs (Permanent magnet synchronous motors) need to be explored.
  • Focus on direct torque and vector control techniques.
  • Synthesize energy consumption and energy recovery breaking.

Research Challenges:

  • Across the torque range and extensive rapidity, it is required to attain accurate regulation.
  • Without impairing the functionality of the system, synthesization of energy recovery breaking is very essential.
  1. Energy Storage System Integration with Renewable Energy

Key Goals: To improve grid capability and flexibility, the synthesization of energy storage systems and renewable energy sources is meant to be simulated.

Significant Research Areas:

  • Pay attention to development of batteries and supercapacitors.
  • For energy storage, explore the power electronic converters.
  • Analysis of energy management and optimization techniques.

Research Challenges:

  • In order to enhance durability of storage, charge and discharge cycles should be stabilized.
  • Crucially, verify the effortless synthesization of grid and renewable sources.
  1. Design of Smart Grid-Connected Inverters

Key Goals: This research highly concentrates on modern control tactics. To connect distributed renewable energy systems with the grid, we must model and simulate smart inverters.

Significant Research Areas:

  • Specifically for grid-tied applications, examine the inverter topologies.
  • As reflecting on voltage and frequency regulation, acquire the benefit of real-time control techniques.
  • Efficiently synthesize the smart grid mechanisms with demand response applications.

Research Challenges:

  • On the basis of different grid scenarios, it needs to assist the consistent function.
  • Bi-directional flow of energy and data is intended to be handled efficiently.
  1. Power Quality Improvement Using Active Filters

Key Goals: In enhancing the power capacity on commercial power systems, the capability of active power filters should be simulated and evaluated.

Significant Research Areas:

  • Perform a detailed study on shunt and series active power models.
  • Exploration of reactive power management and harmonic reduction.
  • On the entire functionality and flexibility of systems, consider the implications.

Research Challenges:

  • In terms of varying load scenarios, develop effective filters.
  • While enhancing the power capacity, least power losses must be assured.
  1. High-Efficiency Power Converters for Solar PV Systems

Key Goals: For solar photovoltaic systems, high-capable DC-AC power converters are required to be created and simulated. Our project mainly intends to enhance the functionality and decrease the deprivation.

Significant Research Areas:

  • We must design inverter models for MPPT (Maximum Power Point Tracking).
  • Based on different solar radiations, investigate the dynamic efficiency of systems.
  • Detailed analysis of heat management and thermal performance.

Research Challenges:

  • Across a broad spectrum of operating scenarios, high-capability of the system should be maintained.
  • In high-power applications, it demands to handle thermal problems.
  1. Electric Vehicle Fast Charging Systems

Key Goals: As regards electric vehicles, model and simulate rapid charging systems. While preserving the battery capacity, it aims to decrease the charging time of electric vehicles.

Significant Research Areas:

  • Focus on high-power DC rapid charging mechanisms.
  • Cooling tactics and thermal management ought to be examined intensively.
  • At the time of instant charging, evaluate the battery health monitoring and management.

Research Challenges:

  • Without impacting the battery durability, instant charging must be assured.
  • Considering the high-efficient power charging, it needs to solve the related thermal problems.

What are the best topics for doing a thesis in control system engineering?

Control engineering system efficiently deals with the process of developing, evaluating and enhancing a control system. In the motive of assisting you in carrying out a thesis on control system engineering, some of the compelling as well as interesting research topics are suggested by us:

  1. Advanced Control Strategies for Renewable Energy Systems

Key Goals: To synthesize the sources of renewable energy such as solar and wind with the power grid application, modern control algorithms should be designed and assessed which assist in handling the function effectively.

Significant Research Areas:

  • Specifically for better power generation and supply, utilize MPC (Model Predictive Control) techniques.
  • For diverse ecological scenarios, investigate the adaptive control algorithms.
  • Regarding the occurrence of sags in renewable energy systems, develop effective control techniques for grid stability.

Research Challenges:

  • On renewable energy sources, it demands to control the diversity of volatility.
  • Power systems with extensive penetration of sustainable energy, we  must assure capability and flexibility.
  1. Autonomous Vehicle Control Systems

Key Goals: In automated vehicles, improve the capacity, integrity and security through exploring and modeling the productive control systems.

Significant Research Areas:

  • Analysis of path planning and motion synthesis.
  • For real-time navigation, examine sensor fusion.
  • Considering the vehicle developments and flexibility, investigate the control techniques.

Research Challenges:

  • Diverse sensors have to be synthesized and assure processing of actual data.
  • To manage evolving and unstable platforms, productive techniques are supposed to be modeled.
  1. Robust Control Systems for Industrial Automation

Key Goals: On the basis of diverse scenarios, we have to enhance the integrity and functionality of industrial automation processes by modeling effective control systems.

Significant Research Areas:

  • Explore the effective methodologies of control models like sliding mode control and H-infinity.
  • Conduct a detailed study on fault detection and resilience.
  • Management of multivariable and nonlinear systems has to be examined.

Research Challenges:

  • Primarily for managing doubts and interruptions, it is required to model controllers.
  • Based on fault scenarios, we should assure the system, if it executes smoothly and remains unaltered.
  1. Intelligent Control Systems for Smart Grids

Key Goals: For smart grids, improve the synthesization, integrity and capability of distributed energy resources by means of creating smart control systems.

Significant Research Areas:

  • Analysis of load balancing and demand response.
  • By implementing smart control systems, synthesize distributed energy resources.
  • In intelligent control systems, examine the cybersecurity and high accessibility features.

Research Challenges:

  • It could be difficult to handle smart grids with various distributed sources.
  • From probable attacks, we need to secure grid systems and assure cybersecurity.
  1. Control Strategies for Robotic Systems

Key Goals: This research concentrates on communication with humans, flexibility and accuracy. For different robotic systems, control tactics ought to be examined and modeled.

Significant Research Areas:

  • In adapting platforms, focus on dynamic control for robots.
  • For secure communication between human and robot, crucially manage the cobots (collaborative robots).
  • Regarding multi-robot systems, path scheduling and motion control are very essential.

Research Challenges:

  • According to dynamic platforms and missions, controllers have to be modeled.
  • Among robots and humans, secure and efficient communication must be assured.
  1. Control of Power Electronic Converters

Key Goals: Considering different applications like EV (Electric vehicles) and renewable energy systems, control mechanisms are meant to be created for power electronic converters.

Significant Research Areas:

  • For power converters, design predictive control algorithms.
  • Make use of control tactics for harmonic mitigation and voltage-stability.
  • Regarding high-power converters, explore real-time management and flexibility.

Research Challenges:

  • It could be complex to manage the non-linear uncertainties of power electronic converters, but it is crucial.
  • In accordance with diverse load scenarios, assure flexible and dynamic function in a significant manner.
  1. Model Predictive Control for Complex Systems

Key Goals: Especially for complicated systems like aerospace applications, power systems and chemical functions, our research intends to model and execute MPC (Model Predictive Control).

Significant Research Areas:

  • Model Predictive Control (MPC) intended to be examined for nonlinear and multivariable systems.
  • Focus on computational capability and real-time execution.
  • On MPC, analyze the flexibility and resilience of systems.

Research Challenges:

  • For real-time execution, effective techniques should be created.
  • Depending on model dynamics and interruptions, resilience and flexibility ought to be assured.
  1. Control Systems for Medical Devices

Key Goals: As a means to improve the security, patient data and performance, control systems need to be created for medical devices.

Significant Research Areas:

  • Perform a detailed analysis on management of robotic surgical instruments.
  • For drug delivery systems, examine the feedback mechanisms.
  • Generally, for prosthetics and rehabilitation devices, it is approachable to regulate models in an effective manner.

Research Challenges:

  • In medical applications, the security and integrity of control systems is expected to be assured.
  • It demands us to manage the complicated patterns of biological systems and devices.
  1. Control of Unmanned Aerial Vehicles (UAVs)

Key Goals: This research mainly emphasizes the ground clearance, flexibility and self-sufficiency. For UAVs (Unmanned Aerial Vehicles), explore and create control systems.

Significant Research Areas:

  • Considerable areas are path planning and automatic navigation.
  • For multi-rotor and fixed-wing UAVs, develop control tactics.
  • Identify the barriers and propose some mitigation techniques.

Research Challenges:

  • Under several ecological scenarios, consistent and authentic functions of systems are supposed to be assured.
  • As reflecting on real-time decision making, sensors and control systems must be synthesized.
  1. Advanced Control Systems for Smart Buildings

Key Goals:  For smart buildings, enhance safety, convenience and capability by developing control systems.

Significant Research Areas:

  • Emphasize on HVAC control and development.
  • Development of lighting and shading control systems.
  • Critically, synthesize the smart grids and renewable energy sources.

Research Challenges:

  • Among various building applications, complicated relationships are required to be handled.
  • In preserving the security and convenience, it demands to assure energy consumption.

Power Electronics Simulation Project Topics

Power Electronics Simulation Project Topics & Ideas

Power Electronics Simulation Project Topics & Ideas across different domains on phdprime.com are listed out read it and explore more ideas by contacting us. Our topics come with concise descriptions tailored to your research interests. Take advantage of the personalized assistance we offer to scholars.

  1. Design of a calorimeter for modern power electronics and electrical machines
  2. Effects of Increasing Power Electronics on System Stability: Results from MIGRATE Questionnaire
  3. Solutions map: A new concept for power electronics compensator design and optimization
  4. Novel and simple method for power electronics compensator design and optimization
  5. Nonlinear Modular State-Space Modeling of Power-Electronics-Based Power Systems
  6. Real-Time Controller-Hardware-in-the-Loop Testing of Power Electronics Converters
  7. Dynamic power flow-based resonance source location method for the large-scale power electronics-dominated power systems
  8. Energy saving by power electronics in household and automotive applications
  9. Investigation of Load-Flow Control within a Power Electronics Enhanced Transmission System
  10. Feasibility Study of Universal Power Electronics Interface Operation in 350 V and 700 V Residential DC Microgrids
  11. The IREQ simulator-a test bench for closed loop testing of controllers of high power electronics apparatus
  12. On the impact of fuel cell system response on power electronics converter design
  13. A series-LC-filtered active damper for ac power electronics based power systems
  14. Pre-charge, Discharge, and Mini-UPS Circuits in Auxiliary Power Network Architecture for 10 kV SiC-Based Power Electronics Building Block
  15. A novel approach for designing and analysing power electronics and control applications
  16. Reducing Voltage and Frequency Fluctuations in Power Systems using Smart Power Electronics Technologies: A Review
  17. Unified power engineering laboratory for electromechanical energy conversion, power electronics, and power systems
  18. Design Guidelines of Rapid Control Prototyping Systems for Power Electronics and Electrical Drives
  19. Integrated test stand design for modern power electronics laboratory exercises
  20. Multi-Objective Co-Design of an Integrated Power Electronics Building Block
Opening Time

9:00am

Lunch Time

12:30pm

Break Time

4:00pm

Closing Time

6:30pm

  • award1
  • award2