Switched time delay control based on neural network for fault detection and compensation in robot

Maincer Dihya, M. Moufid, Boudjedir Chemseddine, Bounabi Moussaab
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引用次数: 0

Abstract

Fault detection in robotic manipulators is necessary for their monitoring and represents an effective support to use them as independent systems. This present study investigates an enhanced method for representation of the faultless system behavior in a robot manipulator based on a multi-layer perceptron (MLP) neural network learning model which produces the same behavior as the real dynamic manipulator. The study was based on generation of residue by contrasting the actual output of the manipulator with those of the neural network; Then, a time delay control (TDC) is applied to compensate the fault, in which a typical sliding mode command is used to delete the time delay estimate produced by the belated signal in order to obtain strong performances. The results of the simulations performed on a model of the SCARA arm manipulator, showed a good trajectory tracking and fast convergence speed in the presence of faults on the sensors. In addition, the command is completely model independent, for both TDC and MLP neural network, which represents a major advantage of the proposed command.
基于神经网络的切换时延控制在机器人故障检测与补偿中的应用
机械臂故障检测是机械臂监控的必要条件,是将机械臂作为独立系统使用的有效支持。本文研究了一种基于多层感知器(MLP)神经网络学习模型的机器人无故障系统行为的增强表示方法,该模型产生与真实动态机械臂相同的行为。通过对比机械手的实际输出和神经网络的输出,基于残差的生成进行研究;然后,采用时延控制(TDC)进行故障补偿,其中使用典型滑模命令删除延迟信号产生的时延估计,以获得较强的性能。在SCARA机械臂模型上的仿真结果表明,该方法在传感器存在故障的情况下具有良好的轨迹跟踪能力和较快的收敛速度。此外,对于TDC和MLP神经网络,该命令是完全独立于模型的,这是该命令的一个主要优点。
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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CiteScore
6.80
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