Power Electronics with Matlab/Simulink
- DC-DC Converters: Learn to design and simulate a variety of DC-DC converter topologies, such as Buck, Boost, and Buck-Boost converters. Analyze their performance, including efficiency and transient response, under different operating conditions.
- AC-DC Converters: Explore the principles of rectification, both uncontrolled and controlled. Simulate rectifier circuits to understand their applications in power supplies.
- DC-AC Converters (Inverters): Understand the design and simulation of single-phase and three-phase inverters, with a focus on Pulse Width Modulation (PWM) control strategies and their impact on performance.
Power Inverters with Matlab/Simulink
- Single-Phase Inverters: Design and simulate single-phase inverters, focusing on modulation techniques and their effects on harmonic distortion and efficiency.
- Three-Phase Inverters: Develop and simulate three-phase inverters used in industrial applications. Explore space vector modulation and its benefits.
- Advanced Inverter Topologies: Get introduced to multilevel inverters and their applications in high-power systems. Simulate different configurations to analyze performance.
Power Drives with Matlab/Simulink
- Motor Drives: Design and simulate motor drives, including DC drives, AC drives, and variable frequency drives. Understand motor control principles and apply them using Matlab/Simulink.
- Control Strategies: Learn and implement various control strategies such as PID control, vector control, and direct torque control in simulations.
- Drive Applications: Explore the applications of motor drives in automotive, manufacturing, and renewable energy sectors. Simulate specific drive systems for a practical understanding.
Renewable Energy Systems with Matlab/Simulink
- Photovoltaic (PV) Systems: Design and simulate PV systems, both grid-connected and standalone. Analyze performance under various conditions and implement Maximum Power Point Tracking (MPPT) techniques.
- Wind Energy Systems: Simulate wind energy conversion systems, studying their aerodynamic and electrical characteristics. Implement control strategies to optimize performance.
- Hybrid Energy Systems: Model and simulate hybrid energy systems that combine multiple renewable sources, such as PV and wind. Analyze system stability and efficiency, and explore energy storage solutions.
- Grid-Connected Renewable Energy Systems: Understand the modeling and simulation of grid-connected renewable energy systems. Focus on grid stability and performance optimization.
EV with Matlab/Simulink
- EV Powertrain Simulation: Design and simulate EV powertrain components, including electric motors, battery management systems, and power electronics. Analyze their performance under different driving conditions.
- Battery Modeling and Management: Model and simulate battery systems, focusing on parameters like state of charge (SoC) and state of health (SoH). Implement battery management algorithms for performance optimization.
- Control Strategies for EVs: Develop and simulate control strategies for electric motors, including vector control and regenerative braking. Analyze their impact on energy efficiency.
- Integration with Renewable Energy: Explore the integration of EVs with renewable energy sources. Simulate PV-powered EV charging stations and analyze the impact on performance and grid stability.
