Pressure observer based adaptive robust trajectory tracking control of a parallel manipulator driven by pneumatic muscles 被引量：1

Pressure observer based adaptive robust trajectory tracking control of a parallel manipulator driven by pneumatic muscles

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摘要 This paper presents a pressure observer based adaptive robust controller (POARC) for posture trajectory tracking of a parallel manipulator driven by three pneumatic muscles without pressure sensors. Due to model errors of the static forces and friction forces of pneumatic muscles, simplified average flow rate characteristics of valves, unknown disturbances of entire system, and unmeasured pressures, there exist rather severe parametric uncertainties, nonlinear uncertainties and dynamic uncertainties in modeling of the parallel manipulator. A nonlinear pressure observer is constructed to estimate unknown pressures on the basis of a single-input-single-output (SISO) decoupling model that is simplified from the actual multiple-input-multiple-output (MIMO) coupling model of the parallel manipulator. Then, an adaptive robust controller integrated with the pressure observer is developed to accomplish high precision posture trajectory tracking of the parallel manipulator. The experimental results indicate that the system with the proposed POARC not only achieves good control accuracy and smooth movement but also maintains robustness to disturbances. This paper presents a pressure observer based adaptive robust controller （POARC） for posture trajectory tracking of a parallel manipulator driven by three pneumatic muscles without pressure sensors. Due to model errors of the static forces and friction forces of pneumatic muscles, simplified average flow rate characteristics of valves, unknown disturbances of entire system, and unmeasured pressures, there exist rather severe parametric uncertainties, nonlinear uncertainties and dynamic uncertainties in modeling of the parallel manipulator. A nonlinear pressure observer is constructed to estimate unknown pressures on the basis of a single-input-single-output （SISO） decoupling model that is simplified from the actual multiple-input-multiple-output （MIMO） coupling model of the parallel manipulator. Then, an adaptive robust controller integrated with the pressure observer is developed to accomplish high precision posture trajectory tracking of the parallel manipulator. The experimental results indicate that the system with the proposed POARC not only achieves good control accuracy and smooth movement but also maintains robustness to disturbances.

作者 ZHU Xiao-cong TAO Guo-liang CAO Jian

机构地区 The State Key Laboratory of Fluid Power Transmission and Control Zhejiang University

出处《Journal of Zhejiang University-Science A(Applied Physics & Engineering)》 SCIE EI CAS CSCD 2007年第12期1928-1937,共10页 浙江大学学报（英文版）A辑（应用物理与工程）

基金 Project (No.50775200) supported by the National Natural Science Foundation of China

关键词气压传动平行操作机械手压力观测 Pneumatic muscle, Parallel manipulator, Pressure observer, Adaptive robust control, Trajectory tracking

分类号 TH138 [机械工程—机械制造及自动化]

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