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3: System Responses and Controls

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Learning Objectives

Compute system time responses with impulse, step, and sinusoidal inputs using inverse Laplace transforms.
Define system bounded-input and bounded-output (BIBO) and asymptotical stability measures for linear time invariant (LTI) systems. Justify if the system is marginally or asymptotically stable. Understand definitions of system response measures such as overshoot, settling time, and rise time.
Understand response characteristics of first and second order systems and the relationship between system pole locations and performance criteria. Learn to analytically calculate response performance criteria such as overshoot and settling time.
Describe the principle of PID (proportional-integral-derivative) control. Conduct its gain tuning utilizing Ziegler-Nichols and direct-tuning approaches.
Describe the model-based control design method and the associated gain-tuning method using the output covariance control (OCC) design method.
Understand the model-based gain scheduled control design method based upon the LPV (linear parameter-varying) control model.

This chapter provides an introduction to control-related techniques used in mechatronic system analysis and controls, including system excitations (impulse, step, sinusoid), the first and second order system responses, system stability (bounded-input/bounded-output stability, asymptotical stability), proportional-integral-derivative (PID) control, and gain tuning. In addition, this chapter provides a brief review of model-based control design and its associated gain tuning method along with machine-learning-based control design methodology.

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