Reference no: EM134474

A Farm Equipment Manufacturer has a need to actively reduce the vibration of the operator's seat using an electrodynamic actuator. The frequency of operation varies from 1 to 10 Hz. Your goal is to develop the active control system of the seat. The seat without control (no actuators or sensors) will be referred to as Uncontrolled Seat.

Part 1 (40% U, 30% G) -Time Domain System Modeling and Analysis -MATLAB

1. Define the physical uncontrolled seat, including seat dimensions, weight, and springs and dampers characteristics.

2. Draw the block diagram of the uncontrolled seat.

3. Plot the open loop displacement response of the uncontrolled seat to a step input

4. Plot the open loop displacement response of the uncontrolled seat to a random input signal

5. Plot the open loop velocity response of the uncontrolled seat to a step input

6. Plot the open loop velocity response of the uncontrolled seat to a random input signal

7. Plot the open loop acceleration response of the uncontrolled seat to a step input

8. Plot the open loop acceleration response of the uncontrolled seat to a random input signal

9. Define the parameters of the actuators and sensors.

10. Draw the open loop block diagram of the actively controlled seat when the controller C(s) = 1

11. Plot the open loop displacement response of the controlled ( C(s) = 1) seat to a step input

12. Plot the open loop displacement response of the controlled ( C(s) = 1) seat to a random input signal

13. Plot the open loop velocity response of the controlled ( C(s) = 1) seat to a step input

14. Plot the open loop velocity response of the controlled ( C(s) = 1) seat to a random input signal

15. Plot the open loop acceleration response of the controlled ( C(s) = 1 ) seat to a step input

16. Plot the open loop acceleration response of the controlled ( C(s) = 1) seat to a random input signal

17. Draw the closed loop block diagram of the actively controlled seat when the controller C(s) = 1 

18. Plot the closed loop displacement response of the controlled ( C(s) = 1) seat to a step input

19. Plot the closed loop displacement response of the controlled ( C(s) = 1) seat to a random input signal

20. Plot the open closed velocity response of the controlled ( C(s) = 1) seat to a step input

21. Plot the closed loop velocity response of the controlled ( C(s) = 1 ) seat to a random input signal

22. Plot the closed loop acceleration response of the controlled ( C(s) = 1) seat to a step input

23. Plot the closed loop acceleration response of the controlled seat ( C(s) = 1) to a random input signal

24. Complete the following table for a step input.

Part 2 (20% U, 10% G) -Time Domain System Modeling and Analysis - SIMULINK

1. Your original system (seat, actuator, and sensor) cannot be modified

2. Uncontrolled seat position, velocity, and acceleration response to a unit step input simulation in one model using graphs as output device.

3. Uncontrolled seat position, velocity, and acceleration response to a random signal (0 to 10 Hz) input simulation in one model using scopes as output device.

4. Controlled seat C(s) = 1 position, velocity, and acceleration response to a unit step input in one model using graphs as output device.

5. Controlled seat C(s) = 1 position, velocity, and acceleration response to a random signal (0 to 10 Hz) input simulation in one model using scope as output device.

6. Reporting: Submit the plots of the Simulink models and each output window including the input signals. Or a total of 16 output windows and 4 models.