Transient Control Improvement on Pneumatic Servoing in Robot System using Fractional-Order PID with Finite-time Prescribed Performance Control

2022 IEEE 12th Symposium on Computer Applications & Industrial Electronics (ISCAIE) Pub Date : 2022-05-21 DOI:10.1109/iscaie54458.2022.9794510

M. I. Putra Azahar, A. Irawan, M. S. Ramli

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Abstract

This paper presents an effective control strategy for an industrial robot's tri-finger pneumatic gripper (TPG) that incorporates with a finite-time prescribed performance control (FT-PPC) with a fractional-order proportional-integral-derivative (FOPID) controller named as FTPPC-FOPID controller. The experiments were carried out with step input trajectories as a fundamental critical input for pneumatic rod-piston on the TPG unit. The results show that, the proposed FTPPC-FOPID controller as compared to the FOPID controller alone has improved the PPVDC rod-piston positioning performances by eliminating the oscillation on the transient response, thus avoiding overshoot, and providing fast settling time as well as steady-state error. Moreover, the proposed control strategy has improved the PPVDC's piston’s pressures with minimum control input oscillation. Overall results show that the proposed FTPPC can improve the feedback controller such as FOPID in controlling a very nonlinear system such as pneumatic servo system in TPG.

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分数阶PID有限时间性能控制对机器人气动伺服系统暂态控制的改进

提出了一种工业机器人三指气动夹持器(TPG)的有效控制策略，该策略将有限时间规定性能控制(FT-PPC)与分数阶比例-积分-导数(FOPID)控制器(FTPPC-FOPID)相结合。实验采用阶跃输入轨迹作为TPG装置上气动杆-活塞的基本关键输入。结果表明，与单独的FOPID控制器相比，所提出的FTPPC-FOPID控制器通过消除瞬态响应上的振荡，从而避免了超调，并提供了快速的稳定时间和稳态误差，提高了PPVDC杆柱定位性能。此外，该控制策略以最小的控制输入振荡提高了PPVDC的活塞压力。总体结果表明，所提出的FTPPC在控制非常非线性的系统(如TPG中的气动伺服系统)方面可以改进FOPID等反馈控制器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE 12th Symposium on Computer Applications & Industrial Electronics (ISCAIE)

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