Title :
Stabilization of Discrete-Time Systems With Multiple Actuator Delays and Saturations
Author :
Bin Zhou ; Zhao-Yan Li ; Zongli Lin
Author_Institution :
Center for Control Theor. & Guidance Technol., Harbin Inst. of Technol., Harbin, China
Abstract :
This paper studies the problems of global and semi-global stabilization of discrete-time linear systems with multiple input saturations and arbitrarily large bounded delays. By developing the methodology of truncated predictor feedback (TPF), state feedback control laws using only the current states of the systems are constructed to solve these problems. The feedback gains are dependent on the delay information of the open-loop system and thus are referred to as delay-dependent feedback. A method for determining the exact condition such that the resulting closed-loop system is asymptotically stable is also presented. Moreover, if the delays in the system are time-varying or even unknown, a modified delay-independent TPF is also established to solve the concerned problems. Numerical example has been worked out to illustrate the effectiveness of the proposed approaches.
Keywords :
actuators; asymptotic stability; closed loop systems; delay systems; discrete time systems; linear systems; open loop systems; predictive control; state feedback; time-varying systems; actuator delay; actuator saturation; asymptotic stability; bounded delay; closed-loop system; delay information; delay-dependent feedback; delay-independent TPF; discrete-time linear system; feedback gain; input saturation; open-loop system; semiglobal stabilization; state feedback control law; time-varying delay; truncated predictor feedback; Actuators; Asymptotic stability; Closed loop systems; Delay; Linear systems; Vectors; Actuator saturation; semi-global stabilization; stabilization; time-delay systems; truncated predictor feedback;
Journal_Title :
Circuits and Systems I: Regular Papers, IEEE Transactions on
DOI :
10.1109/TCSI.2012.2215777
