ANN Enhanced Hybrid Force/Position Controller of Robot Manipulators for Fiber Placement

Robotics Pub Date : 2024-07-13 DOI:10.3390/robotics13070105

José Francisco Villa-Tiburcio, José Antonio Estrada-Torres, R. Hernández-Alvarado, Josue-Rafael Montes-Martínez, Darío Bringas-Posadas, E. Franco-Urquiza

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Abstract

In practice, most industrial robot manipulators use PID (Proportional + Integral + Derivative) controllers, thanks to their simplicity and adequate performance under certain conditions. Normally, this type of controller has a good performance in tasks where the robot moves freely, performing movements without contact with its environment. However, complications arise in applications such as the AFP (Automated Fiber Placement) process, where a high degree of precision and repeatability is required in the control of parameters such as position and compression force for the production of composite parts. The control of these parameters is a major challenge in terms of quality and productivity of the final product, mainly due to the complex geometry of the part and the type of tooling with which the AFP system is equipped. In the last decades, several control system approaches have been proposed in the literature, such as classical, adaptive or sliding mode control theory based methodologies. Nevertheless, such strategies present difficulties to change their dynamics since their design consider only some set of disturbances. This article presents a novel intelligent type control algorithm based on back-propagation neural networks (BP-NNs) combined with classical PID/PI control schemes for force/position control in manipulator robots. The PID/PI controllers are responsible for the main control action, while the BP-NNs contributes with its ability to estimate and compensate online the dynamic variations of the AFP process. It is proven that the proposed control achieves both, stability in the Lyapunov sense for the desired interaction force between the end-effector and the environment, and position trajectory tracking for the robot tip in Cartesian space. The performance and efficiency of the proposed control is evaluated by numerical simulations in MATLAB-Simulink environment, obtaining as results that the errors for the desired force and the tracking of complex trajectories are reduced to a range below 5% in root mean square error (RMSE).

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用于光纤置放的机器人机械手的 ANN 增强型力/位置混合控制器

在实践中，大多数工业机器人机械手都使用 PID（比例+积分+微分）控制器，因为这种控制器简单易用，而且在特定条件下性能良好。通常情况下，这种控制器在机器人自由移动、不与环境接触的情况下性能良好。然而，在诸如 AFP（自动纤维铺放）工艺等应用中，由于生产复合材料部件时对位置和压缩力等参数的控制精度和可重复性要求很高，因此出现了一些复杂问题。这些参数的控制是对最终产品的质量和生产率的一大挑战，这主要是由于部件的几何形状和 AFP 系统所配备的工具类型十分复杂。过去几十年中，文献中提出了多种控制系统方法，如基于经典、自适应或滑模控制理论的方法。然而，由于这些方法在设计时只考虑了部分干扰因素，因此很难改变其动态特性。本文介绍了一种基于反向传播神经网络（BP-NN）的新型智能型控制算法，该算法结合了用于机械手机器人力/位置控制的经典 PID/PI 控制方案。PID/PI 控制器负责主要的控制动作，而 BP-NNs 则能对 AFP 过程的动态变化进行在线估计和补偿。事实证明，所提出的控制既能实现末端执行器与环境之间所需的相互作用力的 Lyapunov 意义上的稳定性，又能实现机器人顶端在笛卡尔空间中的位置轨迹跟踪。通过在 MATLAB-Simulink 环境中进行数值模拟，对所提控制的性能和效率进行了评估，结果表明所需力的误差和复杂轨迹的跟踪误差均减小到均方根误差（RMSE）5% 以下。

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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Robotics

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