Abstract
Because permanent-magnet synchronous linear motors (SLM) still exhibit nonlinear friction, ending effects and time-varying dynamic uncertainties, better control performances cannot be achieved by using common linear controllers. We propose a backstepping approach with three adaptive laws and a beating function to control the motion of permanent-magnet SLM drive systems that enhance the robustness of the system. In order to reduce greater vibration in situations with uncertainty actions in the aforementioned control systems, we propose an adaptive modified recurrent Rogers–Szego polynomials neural network backstepping (AMRRSPNNB) control system with three adaptive laws and reimbursed controller with decorated gray wolf optimization (DGWO), in order to handle external bunched force uncertainty, including nonlinear friction, ending effects and time-varying dynamic uncertainties, as well as to reimburse the minimal rebuild error of the reckoned law. In accordance with the Lyapunov stability, online parameter training method of the modified recurrent Rogers–Szego polynomials neural network (MRRSPNN) can be derived by utilizing an adaptive law. Furthermore, to help reduce error and better obtain learning fulfillment, the DGWO algorithm was used to change the two learning rates in the weights of the MRRSPNN. Finally, the usefulness of the proposed control system is validated by tested results.
Highlights
Linear motors can provide linear motion in the absence of motion translators, such as ball screws, gears and belts that reduce motor limitations and complexity
DGWOcomputer downloads the program running on the DSP
The proposed accuracy in the real-time control was realized by utilizing the DSP control system
Summary
Linear motors can provide linear motion in the absence of motion translators, such as ball screws, gears and belts that reduce motor limitations and complexity. Most linear motors have lower load capacity than other types of linear actuators. The permanent-magnet synchronous linear motor (SLM), with a direct drive design, has some good performance characteristics, such as higher speed, higher precision, less friction, no backlash, maintenance-free operation and extra-high thrust force [1]. The permanent-magnet SLM has been broadly applied in machine tools, semiconductor manufacturing systems and industrial robots [1,2,3]. The permanent-magnet SLM has larger thrust density that is superior to the other linear motors. The backstepping control kill [4,5,6] has been applied in various kinds of linear feedback systems
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