Title :
Modeling and control of a novel X-Y parallel piezoelectric-actuator driven nanopositioner
Author :
Pengbo Liu ; Peng Yan ; Zhen Zhang ; Tongtong Leng
Author_Institution :
Sch. of Mech. Eng., Shandong Univ., Jinan, China
Abstract :
In this paper, a novel X-Y parallel piezoelectric-actuator driven nanopositioner is studied from the perspectives of design optimization, dynamical modeling, as well as controller design for high precision positioning. FEM (Finite Element Method) and dynamical modeling are provided to analyze the mechatronic structure of the proposed two-dimensional nano-stage, where the system model including hysteresis loop is derived analytically and further verified experimentally. A robust control architecture incorporating an H∞ controller and an anti-windup compensator is then developed to deal with the hysteresis and saturation nonlinearities of the piezoelectric actuators. Real time experiments on the positioning of the nano-stage demonstrate good robustness, tracking performance and recovery speed in the presence of saturation.
Keywords :
H∞ control; compensation; control nonlinearities; control system synthesis; design engineering; finite element analysis; hysteresis; mechatronics; nanopositioning; optimisation; piezoelectric actuators; robust control; 2D nanostage; FEM; H∞ controller; X-Y parallel piezoelectric actuator; antiwindup compensator; controller design; design optimization; dynamical modeling; finite element method; hysteresis loop; hysteresis nonlinearities; mechatronic structure; nanopositioner; precision positioning; robust control architecture; saturation nonlinearities; Actuators; Finite element analysis; Hysteresis; Manufacturing processes; Mathematical model; Nanopositioning; Robustness; Mechatronics; Nano systems; Robust control;
Conference_Titel :
American Control Conference (ACC), 2014
Conference_Location :
Portland, OR
Print_ISBN :
978-1-4799-3272-6
DOI :
10.1109/ACC.2014.6859340
