Modeling and Simulink of Droop Control Using Sliding Mode with Virtual Impedance and Latency Resilience
Implementation Plan:
—————————
Scenario 1: (Fast-Adaptive SMC-based Droop)
——————————————————–
Step 1: Initially, we construct a droop control model with battery, PV, wind, 3 DC sources that integrates sliding mode surfaces with virtual impedance and fixed-time convergence.
Step 2: Then, we simulate and collect fast-adaptive SMC controller data under identical load conditions.
Step 3: Next, we calculate active/reactive power errors, and convergence delay using communication-latency constraints based on collected data.
Step 4: Then, we analyze the system’s stability, response time, and error tolerance under load perturbations.
Step 5: Finally, we plot performance metrics for the following
5.1: Time vs. Voltage
5.2: Time vs. Frequency Deviation
5.3: Time vs. Wind Active Power
5.4: Time vs. Wind Reactive Power
5.5: Time vs. Solar Active Power
5.6: Time vs. Solar Reactive Power
5.7: Time vs. Convergence Time
5.8: Time vs. State of Charge
5.9: Time vs. Total Harmonic Distribution
Scenario 2: (Traditional Droop Control)
————————————————-
Step 1: Initially, we construct a droop control model with battery, PV, wind, 3 DC sources using power-voltage (P-V) and reactive power-frequency (Q-f) relationships for inverters.
Step 2: Then, we simulate and collect Traditional Droop Controller data under identical load conditions.
Step 3: Next, we calculate active/reactive power errors, and convergence delay using communication-latency constraints based on collected data.
Step 4: Then, we analyze the system’s stability, response time, and error tolerance under load perturbations.
Step 5: Finally, we plot performance metrics for the following
5.1: Time vs. Voltage
5.2: Time vs. Frequency Deviation
5.3: Time vs. Wind Active Power
5.4: Time vs. Wind Reactive Power
5.5: Time vs. Solar Active Power
5.6: Time vs. Solar Reactive Power
5.7: Time vs. Convergence Time
5.8: Time vs. State of Charge
5.9: Time vs. Total Harmonic Distribution
Software Requirements:
—————————–
1. Development Tool: Matlab-R2023a/Simulink
2. Operating System: Windows-10 (64-bit)
Note:
——-
1) If the plan does not meet your requirements, provide detailed steps, parameters, models, or expected results in advance. Once implemented, changes won’t be possible without prior input; otherwise, we’ll proceed as per our implementation plan.
2) If the plan satisfies your requirement, Please confirm with us.
3) Project based on Simulation only, not a real time project.
4) Please understand that any modifications made to the confirmed implementation plan will not be made after the project development.
