Implementation Plan:
Step 1: Initially, we will construct the grid-tied PMSG wind energy system model in Simulink with LVRT and HVRT CapabilitiesStep 2: Then, we integrate the Active Disturbance Rejection Controller (ADRC) in the model.
Step 3: Next, we simulate the system to collect data such as voltage, current, power, rotor speed and torque.
Step 4: Next, we analyze grid disturbance conditions like symmetrical fault, asymmetrical fault, voltage swell, and parameter variations based on collected data.
Step 5: Then, we analyze disturbance rejection, and power quality based on collected data.
Step 6: Finally, we plot performance metrics for the following:
6.1: Time vs Active power (p.u)
6.2: Time vs Rotor speed (pu)
6.3: Time vs Electromagnetic Torque(p.u)
6.4: Time vs DC link voltage(pu)
6.5: Time vs stator current(p.u)
Step 1: Initially, we will construct the grid-tied PMSG wind energy system model in Simulink with LVRT and HVRT CapabilitiesStep 2: Then, we integrate the Proportional–Resonant controller (PR) in the model.
Step 3: Next, we simulate the system to collect data such as voltage, current, power, rotor speed and torque.
Step 4: Next, we analyze grid disturbance conditions like symmetrical fault, asymmetrical fault, voltage swell, and parameter variations based on collected data.
Step 5: Then, we analyze disturbance rejection, and power quality based on collected data.
Step 6: Finally, we plot performance metrics for the following:
6.1: Time vs Active power (p.u)
6.2: Time vs Rotor speed (pu)
6.3: Time vs Electromagnetic Torque(p.u)
6.4: Time vs DC link voltage(pu)
6.5: Time vs stator current(p.u)
Step 1: Initially, we will construct the grid-tied PMSG wind energy system model in Simulink with LVRT and HVRT CapabilitiesStep 2: Then, we integrate the Proportional–Integral controller (PI) in the model.
Step 3: Next, we simulate the system to collect data such as voltage, current, power, rotor speed and torque.
Step 4: Next, we analyze grid disturbance conditions like symmetrical fault, asymmetrical fault, voltage swell, and parameter variations based on collected data.
Step 5: Then, we analyze disturbance rejection, and power quality based on collected data.
Step 6: Finally, we plot performance metrics for the following:
6.1: Time vs Active power (p.u)
6.2: Time vs Rotor speed (pu)
6.3: Time vs Electromagnetic Torque(p.u)
6.4: Time vs DC link voltage(pu)
6.5: Time vs stator current(p.u)
1. Development Tool: MATLAB R2023a/Simulink or above
2. Operating System: Windows-10 (64-bit) or aboveNote:
1) If the proposed plan does not fully align with your requirements, please provide all necessary details—including steps, parameters, models, and expected outcomes—in advance. Kindly ensure that any missing configurations or specifications are clearly outlined in the plan before confirming.
2) If there’s no built-in solution for what the project needs, we can always turn to reference models, customize our own, different math models or write the code ourselves to fulfil the process.
3) If the plan satisfies your requirement, Please confirm with us.
4) Project based on Simulation only.
