You are now given a problem to test your knowledge of this chapter's objectives. Refer to the antenna azimuth position control system shown in Appendix A2, Configuration 2. Assume an open-loop system (feedback path disconnected) and do the following: a. Predict the open-loop angular velocity response of the power amplifier, motor, and load to a step voltage at the input to the power amplifier. b. Find the damping ratio and natural frequency of the open-loop system. c. Derive the open-loop angular velocity response of the power amplifier, motor, and load to a step-voltage input using transfer functions. d. e. State Space SS MATLAB ML Obtain the open-loop state and output equations. Use MATLAB to obtain a plot of the open-loop angular velocity response to a step-voltage input. You are now given a problem to test your knowledge of this chapter's objectives. Refer to the antenna azimuth position control system shown in Appendix A2, Configuration 2. Assume an open-loop system (feedback path disconnected) and do the following: a. Predict the open-loop angular velocity response of the power amplifier, motor, and load to a step voltage at the input to the power amplifier. b. Find the damping ratio and natural frequency of the open-loop system. c. Derive the open-loop angular velocity response of the power amplifier, motor, and load to a step-voltage input using transfer functions. d. e. State Space SS MATLAB ML Obtain the open-loop state and output equations. Use MATLAB to obtain a plot of the open-loop angular velocity response to a step-voltage input.
You are now given a problem to test your knowledge of this chapter's objectives. Refer to the antenna azimuth position control system shown in Appendix A2, Configuration 2. Assume an open-loop system (feedback path disconnected) and do the following: a. Predict the open-loop angular velocity response of the power amplifier, motor, and load to a step voltage at the input to the power amplifier. b. Find the damping ratio and natural frequency of the open-loop system. c. Derive the open-loop angular velocity response of the power amplifier, motor, and load to a step-voltage input using transfer functions. d. e. State Space SS MATLAB ML Obtain the open-loop state and output equations. Use MATLAB to obtain a plot of the open-loop angular velocity response to a step-voltage input. You are now given a problem to test your knowledge of this chapter's objectives. Refer to the antenna azimuth position control system shown in Appendix A2, Configuration 2. Assume an open-loop system (feedback path disconnected) and do the following: a. Predict the open-loop angular velocity response of the power amplifier, motor, and load to a step voltage at the input to the power amplifier. b. Find the damping ratio and natural frequency of the open-loop system. c. Derive the open-loop angular velocity response of the power amplifier, motor, and load to a step-voltage input using transfer functions. d. e. State Space SS MATLAB ML Obtain the open-loop state and output equations. Use MATLAB to obtain a plot of the open-loop angular velocity response to a step-voltage input.
Power System Analysis and Design (MindTap Course List)
6th Edition
ISBN:9781305632134
Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Chapter12: Power System Controls
Section: Chapter Questions
Problem 12.4P
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only a, b and c please
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