- 12.12.1: Control of the attitude of a missile by controlling the fin angle ,...
- 12.12.2: a. Design an electrical compensator to obtain n = 4 while keeping =...
- 12.12.3: It is desired to control the angular displacement of a space vehicl...
- 12.12.4: When proportional control is applied to the following plant using a...
- 12.12.5: The speed 1 of the load is to be controlled with the torque Td acti...
- 12.12.6: The block diagram of a speed control system is shown in Figure P12....
- 12.12.7: The block diagram of a position control system is shown in Figure P...
- 12.12.8: It is desired to control the angular displacement of a space vehicl...
- 12.12.9: following form will give a settling time of no more than 2 sec and ...
- 12.12.10: Consider a plant whose open-loop transfer function is G(s)H(s) = 1 ...
- 12.12.11: a) The equations of motion of the inverted pendulum model were deri...
- 12.12.12: A certain unity feedback system has the following open-loop system ...
- 12.12.13: shows a pneumatic positioning system, where the displacement x is c...
- 12.12.14: The height h2 in Figure P12.14 can be controlled by adjusting the f...
- 12.12.15: Rolling motion of a ship can be reduced by using feedback control t...
- 12.12.16: The open-loop transfer function of a certain unity feedback system ...
- 12.12.17: The following transfer functions are the forward transfer function ...
- 12.12.18: Remote control of systems over great distance, such as required wit...
- 12.12.19: Room Temperature sensor L Steam v D 5 L v Blower Heat exchanger hea...
- 12.12.20: The block diagram of a position control system is shown in Figure P...
- 12.12.21: The speed 2 of the load is to be controlled with the torque T actin...
- 12.12.22: Design a compensator for the plant G p(s) = 2 s2 + 2s so that the s...
- 12.12.23: Figure P12.2 shows a pneumatic positioning system, where the displa...
- 12.12.24: The block diagram of a position control system is shown in Figure P...
- 12.12.25: The block diagram of a position control system is shown in Figure P...
- 12.12.26: Consider a unity-feedback system having the open-loop transfer func...
- 12.12.27: Two independent feedback control systems are needed to position the...
- 12.12.28: Automatic guided vehicles are used in factories and warehouses to t...
- 12.12.29: With the PI gains set to KP = 6 and KI = 50 for the plant G p(s) = ...
- 12.12.30: In Example 12.1.4 a lag-lead compensator was designed by canceling ...
- 12.12.31: Solve 12.2 using MATLAB.
- 12.12.32: Solve 12.4 using MATLAB.
- 12.12.33: Solve 12.5 using MATLAB.
- 12.12.34: Solve 12.6 using MATLAB.
- 12.12.35: Solve 12.12 using MATLAB.
- 12.12.36: Solve 12.13 using MATLAB.
- 12.12.37: Solve 12.14 using MATLAB.
- 12.12.38: Solve 12.15 using MATLAB.
- 12.12.39: Solve 12.18 using MATLAB.
- 12.12.40: Solve 12.28 using MATLAB.
- 12.12.41: Solve 12.29 using MATLAB.
- 12.12.42: Refer to Example 12.1.1, in which a PID controller was designed to ...
- 12.12.43: Consider 12.19. Use Simulink to determine how large the dead time c...

# Solutions for Chapter 12: Compensator Design and the Bode Plot

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ISBN: 9780073398068

Solutions for Chapter 12: Compensator Design and the Bode Plot

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