M Tech Thesis Electrical Engineering

M Tech Thesis Electrical Engineering existing in the level of all ranges of scholars are listed in this page. It is hard for scholars to get the right M Tech Thesis Topic on Electrical Engineering, so contact phdprime.com we will give you novel care for all of your research work.  Together with major aspects and research challenges, we offer numerous possible thesis topics that utilize Simulink:

1. Design and Simulation of a Grid-Tied Solar Photovoltaic System

Aim: Through the utilization of Simulink, we intend to model and simulate a grid-tied solar photovoltaic (PV) framework. It significantly enhances energy output and assures consistent grid combination.

Major Elements:

• PV Array Model: By employing a in-built PV array block of Simulink, it is appreciable to simulate a PV array.
• MPPT Algorithm: As a means to improve the power output, our team focuses on applying Maximum Power Point Tracking (MPPT).
• Inverter Design: To transform DC to AC power for grid integration, we plan to construct an inverter system.
• Grid Integration: Typically, the communication among the solar PV model and the electrical grid has to be formulated.

Significant Challenges:

• It is crucial to handle the changeability of solar power and its influence on grid flexibility.
• For the renewable energy combination, focus on assuring the adherence to grid codes and principles.

2. Simulation of Electric Vehicle Charging Station Using Simulink

Aim: Concentrating on energy management and grid influence analysis, our team creates and simulates a system of an electric vehicle (EV) charging station.

Major Elements:

• EV Battery Model: It is approachable to simulate various kinds of EV batteries and their charging features.
• Power Electronics: For handling the charging procedures, we plan to model and simulate power converters.
• Energy Management System: In order to improve energy utilization and decrease grid influence, suitable methods should be constructed.
• Integration with Renewable Energy: Specifically, for EV charging, our team investigates the combination of wind or solar energy.

Significant Challenges:

• It is challenging to stabilize the load on the grid with the requirement from numerous EVs.
• In order to decrease energy expenses and charging times, intend to apply effective charging policies.

3. Simulation and Control of Wind Turbine Systems

Aim: By means of utilizing Simulink, it is significant to design and simulate a wind turbine model. For enhancing energy capture and assuring grid flexibility, control policies have to be concentrated.

Major Elements:

• Wind Turbine Model: To design the aerodynamic and mechanical factors of a wind turbine, we employ Simulink.
• Power Electronics and Control: For the generator and power converters, suitable controllers should be formulated.
• Grid Integration: It is approachable to simulate the communication of the wind turbine with the power grid.
• Fault Analysis: As a means to evaluate the model’s credibility and reaction to grid disruptions, our team focuses on carrying out fault analysis.

Significant Challenges:

• The process of sustaining grid flexibility and handling the changeability of wind power is determined as significant.
• To manage various operating situations and failures, aim to model efficient control models.

4. Advanced Control Techniques for Power Electronic Converters

Aim: For power electronic converters employed in renewable energy models, we intend to model and simulate innovative control approaches.

Major Elements:

• Converter Model: Generally, to design different kinds of power electronic converters such as DC-AC, DC-DC, our team aims to utilize Simulink.
• Control Algorithms: It is significant to apply innovative control methods like model predictive control, PID, or fuzzy logic.
• Stability Analysis: Under various operating situations, we plan to carry out flexibility analysis of the control models.
• Efficiency Optimization: In order to improve the performance of power conversion, focus on constructing efficient policies.

Significant Challenges:

• Suitable control models have to be modelled in such a manner to adjust to varying load and resource situations.
• Under differing input and output situations, it is important to assure that the converters function in an effective manner.

5. Design and Simulation of a Microgrid System

Aim: Through the utilization of Simulink, we create and simulate a microgrid framework. It significantly improves energy management and combines numerous renewable energy resources in an efficient way.

Major Elements:

• Microgrid Model: Encompassing energy storage, solar panels, and wind turbines, our team designs a microgrid.
• Energy Management System: To handle energy dissemination and storage, it is appreciable to create suitable control methods.
• Grid Interaction: The communication among the microgrid and the major grid has to be simulated.
• Fault Tolerance: For sustaining microgrid processes at the time of grid failures, we plan to apply and assess policies.

Significant Challenges:

• Within the microgrid, focus on stabilizing the energy delivery and requirement.
• It is crucial to assure the consistent process at the time of grid-connected and islanded conditions.

6. Simulation of Power Quality Improvement Techniques

Aim: For enhancing power quality in electrical models, our team models and simulates approaches. Therefore, it significantly assists in voltage flexibility, harmonic mitigation, and reactive power wages.

Major Elements:

• Power Quality Model: Focus on simulating usual power quality problems like reactive power, voltage fluctuations, and harmonics.
• Compensation Techniques: It is appreciable to model and apply approaches such as dynamic voltage restorers, active filters, and static VAR compensators.
• Control Strategies: As a means to track and enhance power quality in actual-time, we plan to construct control methods.
• Grid Interaction: On grid flexibility and effectiveness, our team aims to examine the influence of these approaches.

Significant Challenges:

• In actual-time, the way of detecting and reducing different power quality problems are determined as significant.
• Without impacting the entire effectiveness of the model, focus on combining power quality enhancement approaches.

7. Modeling and Simulation of Smart Electric Grids

Aim: The smart grid models have to be designed and simulated which integrates several aspects with Simulink such as actual-time tracking, innovative metering, and demand response.

Major Elements:

• Smart Grid Model: Along with characteristics such as automated control, actual-time tracking, and demand-side management, we focus on simulating a smart grid.
• Advanced Metering Infrastructure (AMI): Among smart meters and the grid, it is better to formulate the communication and data transfer.
• Demand Response Strategies: In order to handle extreme load and decrease energy utilization, our team creates and simulates policies.
• Cybersecurity Measures: Safety criterions has to be applied to secure the grid in opposition to cyber assaults.

Significant Challenges:

• Within the smart grid, it is crucial to assure credible interaction and data transfer.
• In order to secure grid processes, suitable effective cybersecurity criterions must be constructed.

8. Simulation of Energy Management Systems for Buildings

Aim: To improve energy utilization and combine renewable energy resources, our team intends to model and simulate an energy management system (EMS) for buildings.

Major Elements:

• Building Model: With different energy loads and renewable energy resources, it is approachable to simulate a building.
• EMS Control: Encompassing peak shaving and load shifting, we focus on creating methods for enhancing energy utilization.
• Integration with Renewables: Together with the energy model of buildings, design the combination of wind turbines, energy storage, and solar panels.
• Real-Time Monitoring: For energy utilization, our team applies tracking and regulation in actual-time.

Significant Challenges:

• In actual-time, intend to stabilize energy delivery and requirement.
• It is important to combine numerous energy resources and enhance their utilization.

What is a project I can work on to combine mechanical engineering and electrical engineering?

Mechanical engineering and electrical engineering are determined as the fast emerging fields in current years. We provide numerous project plans that integrate these two domains in an efficient manner:

1. Autonomous Mobile Robot

Goal: Through the utilization of sensors and control models, our team focuses on modeling and designing an automated robot in such a way that contains the capability to move through various platforms, carry out certain missions, and prevent difficulties. 

Significant Elements:

• Mechanical Structure: To assure mobility and flexibility, we aim to model the wheels, chassis, and suspension framework.
• Sensors: For problem identification and navigation, it is appreciable to combine infrared, ultrasonic, and LIDAR sensors.
• Control System: An embedded model has to be created for sensor data processing and motor control through the utilization of FPGA or microcontroller.
• Power System: Typically, for effective power dissemination, our team plans to model a battery management framework.

Potential Challenges:

• For problem identification and navigation, actual-time data processing should be assured.
• It is significant to model an efficient mechanical infrastructure which contains the capability to confront various environments.

2. Solar-Powered Water Pumping System

Goal: Generally, a solar-based water pumping model has to be constructed which could be employed for irrigation or delivering water to remote regions.

Significant Elements:

• Solar Panels: Generally, this is useful for offering power for the framework.
• Pump Design: To function in adjustable power inputs, we intend to model an effective water pump.
• Power Electronics: In order to control the power from the solar panels to the pump, it is appreciable to formulate a DC-DC converter.
• Control System: Our team focuses on applying a microcontroller-related model as a means to track and regulate the energy utilization and water flow.

Potential Challenges:

• For various flow levels and head heights, the pump model should be improved.
• It is significant to assure effective power conversion from the solar panels to the pump.

3. Hybrid Electric Vehicle (HEV) System

Goal: As a means to decrease emissions and enhance fuel efficacy, our team aims to model a hybrid electric vehicle framework which is capable of integrating a traditional internal combustion engine with an electric motor.

Significant Elements:

• Mechanical System: Encompassing the combination of the internal combustion engine and electric motor, it is approachable to model the drivetrain.
• Battery Management System: Specifically, for handling battery charging and discharging, we create an appropriate framework.
• Control System: To regulate the power dissemination among the engine and the electric motor, an effective model has to be applied.
• Power Electronics: For effective energy exchange among the drive train, battery, and motor, our team models inverters and converters.

Potential Challenges:

• The power output from the electric motor and the internal combustion engine should be stabilized.
• It is crucial to model an effective energy storage and management framework.

4. Smart Prosthetic Limb

Goal: In order to offer improved efficiency and flexibility for users, we intend to construct a smart prosthetic limb.

Significant Elements:

• Mechanical Design: Generally, for the prosthetic limb, it is better to develop a lightweight and ergonomic infrastructure.
• Sensors: To identify muscle activities or behaviour, our team focuses on combining sensors.
• Actuators: Generally, to analyse behaviour and dynamic suggestion, electric motors or servos should be utilized.
• Control System: As a means to process sensor data and regulate the actuators, we plan to create a microcontroller-related framework.

Potential Challenges:

• It is important to make sure that the prosthetic limb reacts to user inputs in a precise manner.
• A suitable framework should be formulated in such a manner that is convenient and simple to utilize for the wearer.

5. Wind Turbine with Energy Storage System

Goal: With a combined energy storage approach, our team plans to model and simulate a wind turbine framework to offer reliable power output.

Significant Elements:

• Mechanical Structure: To enhance wind energy capture, it is approachable to model the turbine blades and tower.
• Generator: A suitable generator must be chosen and designed to transform mechanical energy to electrical energy.
• Energy Storage: As a means to conserve excess energy, we aim to combine batteries or supercapacitors.
• Control System: For handling power generation and storage, aim to create a control model.

Potential Challenges:

• The mechanical infrastructure could contain the capacity to confront differing wind loads. The way of assuring this is examined as crucial.
• The charge and discharge cycles of the energy storage framework should be handled in an effective way.

6. Automated Greenhouse System

Goal: To regulate the platform, we intend to model an automated greenhouse model which employs actuators and sensors. It significantly improves the plant development.

Significant Elements:

• Structural Design: Along with autonomous windows and ventilation models, it is approachable to model the greenhouse architecture.
• Sensors: Typically, humidity, light, temperature, and soil moisture sensors have to be combined.
• Control System: As a means to track and regulate the greenhouse platform, our team focuses on constructing a microcontroller-related framework.
• Irrigation System: On the basis of sensor inputs, adapt water supply by modeling an automated irrigation framework.

Potential Challenges:

• For efficient plant development, it is significant to sustain a reliable platform.
• The model is energy-effective and could function in an automatic way. The process of assuring this is important.

7. Smart Grid with Renewable Energy Integration

Goal: By incorporating different renewable energy resources, our team focuses on constructing a smart grid system. For effective energy management, it employs intelligent control frameworks.

Significant Elements:

• Grid Model: A system of power grid has to be developed which encompasses renewable resources such as wind turbines and solar panels.
• Sensors and Communication: Specifically, for data transfer, our team utilizes sensors for actual-time tracking and communication models.
• Energy Management System: For energy storage management, demand response, and load stabilizing, it is appreciable to construct methods.
• Control System: To handle the combination of renewable energy resources, we focus on employing PLCs or microcontrollers.

Potential Challenges:

• In spite of the changeability of renewable energy resources, it is significant to assure consistent and steady power delivery.
• For handling distributed energy sources, focus on constructing efficient communication and control policies.

8. Renewable Energy-Powered Autonomous Vehicle

Goal: It is approachable to model an autonomous vehicle that is provided with the abilities of self-navigation and functions on renewable energy resources such as wind or solar power.

Significant Elements:

• Energy System: To energize the vehicle, we intend to combine wind turbines or solar panels.
• Mechanical Design: Appropriate for autonomous problem identification, it is appreciable to develop a chassis and propulsion framework.
• Navigation System: For navigation and problem identification, our team utilizes LIDAR, GPS, and camera models.
• Control System: A control model has to be constructed for autonomous driving and energy management.

Potential Challenges:

• It is significant to assure that the vehicle could function consistently only on renewable energy.
• For different environments and situations, intend to construct efficient navigation and control models.

9. Intelligent HVAC System

Goal: To sustain convenience levels and improve energy utilization, we plan to create a smart heating, ventilation, and air conditioning (HVAC) framework which utilizes sensors and methods of machine learning.

Significant Elements:

• Sensors: Our team aims to combine humidity, temperature, and air quality sensors.
• Control System: To process sensor data and regulate the HVAC elements, it is beneficial to employ a microcontroller or embed model.
• Machine Learning Algorithms: Suitable and efficient methods should be applied to improve energy effectiveness and study utilization trends.
• Energy Management: As a means to combine with renewable energy resources or smart grids, our team models the framework.

Potential Challenges:

• To forecast and adapt to user priorities and ecological variations, focus on creating effective methods.
• It is important to assure that the model decreases functional expenses and is energy-effective.

M Tech Thesis Electrical Engineering Topics & Ideas

M Tech Thesis Electrical Engineering Topics & Ideas that paves a fresh start up for your career are accompanied by phdprime.com team. We are fulfilled with 1000+ novel ideas on emerging trending on your interested area. Drop to phdprime.com all your doubts we will give you novel care throughout your research.

1. Power electronics packaging and miniature using chip-scale packaged power devices
2. Reliability Modelling of Power Electronics with Mission Profile Forecasting for Long-Term Planning
3. A multivariable modeling approach for the design of Power Electronics Based DC Distribution Systems in diesel-electric vessels
4. Design and analysis artificial intelligence (AI) research for power supply — power electronics expert system (PEES)
5. A study into the impact of the choice of Maximum Power Point Tracking Technique on the Reliablilty of the Power Electronics Interface for Photovoltaic Systems
6. How to change the landscape of power electronics with wide bandgap power devices
7. Simultaneous active power filter and G2V (or V2G) operation of EV on-board power electronics
8. A novel power line communication technique based on power electronics circuit topology
9. Power electronics design for a direct-driven turbo compressor used as advanced high-lift system in future aircraft
10. Thermal Design Considerations for Integrated Power Electronics Modules based on Temperature Distribution Cases Study
11. Integrating active, passive and EMI-filter functions in power electronics systems:a case study of some technologies
12. Interactive Power Electronics Seminar (iPES)-a web-based introductory power electronics course employing Java-applets
13. Introducing power electronics technologies into the aerospace engineering undergraduate curriculum
14. Distributed software architecture of PEBB-based plug and play power electronics systems
15. A Unique Approach to Power Electronics and Motor Cooling in a Hybrid Electric Vehicle Environment
16. A Modular and Scalable Power Electronics Device for the Control of Electric Drives
17. Customized power quality supply system by use of power electronics and its realization using three phase four wire AC system
18. Digital simulation of power systems and power electronics using the MATLAB/Simulink Power System Blockset
19. Power Electronics course: Analysis and evaluation of the educational software and the environment learning
20. Real-time Co-Simulation for Electrical and Thermal Analysis of Power Electronics