Title :
Optimal linear modeling and its applications on swing-up and stabilization control for Rotary Inverted Pendulum
Author :
Zhang Jian ; Zhang Yongpeng
Abstract :
Through the conventional Jacobian linearization, its operation has to be limited in the neighborhood of equilibrium. To address the control requirement in off-equilibrium region, optimal linearization is introduced to describe the exact dynamics at any operating point with minimal approximation error. In the illustrative example of Rotary Inverted Pendulum, a universal dynamic nonlinear model is firstly developed. Then its local linearized model is updated by every sampling period to match with the current operating point. Meanwhile, its controller is also updated to correspond with the updated local model. Thus, swing-up control and balance control can be both implemented through a unified Linear Quadratic Regulator controller, which can effectively avoid control law switching in the two stages.
Keywords :
approximation theory; linear quadratic control; linearisation techniques; nonlinear control systems; stability; Jacobian linearization; balance control; local linearized model; minimal approximation error; off-equilibrium region; optimal linear modeling; rotary inverted pendulum; sampling period; stabilization control; swing-up control; unified linear quadratic regulator controller; universal dynamic nonlinear model; Control systems; DC motors; Equations; Jacobian matrices; Mathematical model; Nonlinear dynamical systems; Linear Quadratic Regulator; Nonlinear System; Optimal Linearization; Rotary Inverted Pendulum;
Conference_Titel :
Control Conference (CCC), 2011 30th Chinese
Conference_Location :
Yantai
Print_ISBN :
978-1-4577-0677-6
Electronic_ISBN :
1934-1768
