Step by Step Implementation of Advanced Energy System Design and Control for PV, Grid, and EV Applications

This online program offers a structured, step-by-step implementation of advanced PV–Grid–EV energy system design and control using MATLAB/Simulink. The course focuses on converter design, DC bus regulation, inverter control, and EV charging operation, combining theoretical foundations with practical simulation workflows suitable for real-world and research applications. 🔹 Session 1: PV System Modeling & DC-DC Converter Control ☀️ PV array modeling and characteristics under irradiance changes 📈 Implementation of MPPT (Perturb & Observe) algorithm ⚙️ Design and control of DC-DC boost and buck converters 📐 Inductor and capacitor sizing with ripple constraints 🔄 Power flow from PV to common DC bus 🔹 Session 2: DC Bus Regulation & Energy Storage Management 🔋 Role of the common DC bus in hybrid energy systems 🔁 Bidirectional converter control for battery charging/discharging 📉 DC link voltage regulation under load and generation mismatch ⚡ Power balancing among PV, battery, DC load, and EV charger 🧪 Simulation of surplus and deficit operating scenarios 🔹 Session 3: Grid-Connected Inverter & EV Charging Operation 🌐 Three-phase inverter modeling and control architecture 🧭 Phase-Locked Loop (PLL) for grid synchronization 🔄 dq transformation and decoupled power control ⚡ Unity power factor operation using d-axis and q-axis currents 🚗 EV charging modes (PV-assisted, battery-assisted, grid-assisted) 📊 Result analysis and control performance evaluation 🎯 Key Learning Outcomes ✅ Understand complete PV–Grid–EV system architecture ✅ Implement MPPT, DC bus control, and inverter synchronization ✅ Analyze power flow and stability in EV charging stations