Precise Position Control of Quanser Servomotor using Fractional Order Fuzzy PID Controller

2020 IEEE Bombay Section Signature Conference (IBSSC) Pub Date : 2020-12-04 DOI:10.1109/IBSSC51096.2020.9332216

Rohit Bhimte, Kalyani Bhole-Ingale, Pritesh Shah, R. Sekhar

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引用次数: 8

Abstract

Sophisticated automation is dependent upon industrial robots with precise position control servomotors. In the present work, a fractional order fuzzy PID controller (FOFPID) was designed to improve the position control response of a rotary servo system. The control errors and their fractional derivatives were applied as input scaling factors to the fuzzy logic controller (FLC). Fuzzy inference system (FIS) was employed to restrict performance indices in control signals. FOFPID performance for a Quanser servomotor was compared against PID, fractional order PID and fuzzy PID (FPID) controllers in terms of both simulations and hardware implementation. The controller performance evaluation metrics included time domain characteristics such as rise, peak, settling times and over / undershoots. The integral absolute and integral time absolute errors were also evaluated for comparisons among the different controllers. Results establish that only the FOFPID controller achieves zero percent over and undershoots. It also attains better set point tracking over other controllers. Thus, FOFPID controller is the key to precision robotics in the smart factories of tomorrow.

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分数阶模糊PID控制器在舵机伺服电机精确位置控制中的应用

复杂的自动化依赖于具有精确位置控制伺服电机的工业机器人。为了改善旋转伺服系统的位置控制响应，设计了分数阶模糊PID控制器(FOFPID)。将控制误差及其分数阶导数作为模糊控制器(FLC)的输入比例因子。采用模糊推理系统(FIS)对控制信号中的性能指标进行约束。从仿真和硬件实现两方面比较了全捷伺服电机FOFPID与PID、分数阶PID和模糊PID (FPID)控制器的性能。控制器性能评估指标包括时域特征，如上升、峰值、稳定时间和过/欠冲。对不同控制器的积分绝对误差和积分时间绝对误差进行了比较。结果表明，只有FOFPID控制器达到零过冲和欠冲。与其他控制器相比，它还具有更好的设定点跟踪。因此，FOFPID控制器是未来智能工厂中精密机器人技术的关键。

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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2020 IEEE Bombay Section Signature Conference (IBSSC)

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