期刊
ISA TRANSACTIONS
卷 132, 期 -, 页码 444-461出版社
ELSEVIER SCIENCE INC
DOI: 10.1016/j.isatra.2022.06.012
关键词
Dynamic model; Compensation control; Dynamic external loads; Pneumatic muscle; Soft actuator
This study proposes a novel high-order modified dynamic model of the pneumatic muscle actuator (PMA) based on its physical properties and working principle to accurately describe its nonlinear, time-varying, and hysteresis characteristics. A global fast terminal sliding mode controller with a modified model-based radial basis function (RBF) neural network disturbance compensator (RBF-GFTSMC) is designed to address the PMA's nonlinear hysteresis problem in high-frequency movements. Experimental studies on a designed PMA platform show that the RBF-GFTSMC exhibits superior trajectory tracking performance and disturbance compensation capability under wide-ranging frequencies and external loads, making it potentially suitable for achieving precise control of PMA-actuated robots.
Dynamic behaviour of the pneumatic muscle actuator (PMA) is conventionally modelled as a pressure -based first-order equation under discrete loads, which cannot exactly describe its dynamic features. Considering PMA's nonlinear, time-varying and hysteresis characteristics, we propose a novel high -order modified dynamic model of PMA based on its physical properties and working principle, with coefficients being identified under external dynamic loads. To tackle PMA's nonlinear hysteresis problem in high-frequency movements, a global fast terminal sliding mode controller with the modified model-based radial basis function (RBF) neural network disturbance compensator (RBF-GFTSMC) is designed. Comparison experimental studies are carried on a designed PMA platform that can provide continuously changing loads. Results show that the RBF-GFTSMC has superior trajectory tracking performance and disturbance compensation capability under wide-ranged frequencies and external loads, which can be potentially used to achieve precise control of PMA-actuated robots. (c) 2022 ISA. Published by Elsevier Ltd. All rights reserved.
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