A novel robust online sustainable adaptation dynamics control method for robot movement by wheel type Online publication date: Thu, 14-Mar-2024
by Nguyen Minh Quang; Le Thi Phuong Thanh; Nguyen Tien Tung
International Journal of Mechatronics and Manufacturing Systems (IJMMS), Vol. 16, No. 4, 2023
Abstract: A novel robust control algorithm called reinforcement learning online sustainable adaptive dynamic control (RLOSADC) was developed to solve the problem of approximation for nonlinear systems with absolutely no information about internal dynamics. The proposed control model was built based on a new algorithm called optimise cooperation many nonlinear systems (OCMNO) with powerful features and convergence capabilities. New and unique features of the proposed model are shown through a highly flexible design and control procedure. The traditional robot dynamic model is transformed into a tight feedback nonlinear system model for designing 'integrated' kinetic and dynamic control laws to overcome the disadvantages of the previous method. The RLOSADC model has been applied to cling control robust, sustainable adaptation for optimising the kinematic and dynamic clinging quality indicators for robot movement by wheel type (RMWT). Numerical and experimental simulation results on RMWT show the effectiveness of the proposed RLOSADC control model.
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