Adaptive Approximation Sliding-Mode Control of an Uncertain Continuum Robot with Input Nonlinearities and Disturbances

IF 1.8 4区计算机科学 Q3 ENGINEERING, BIOMEDICAL

Applied Bionics and Biomechanics Pub Date : 2024-03-06 DOI:10.1155/2024/8533606

Shoulin Xu

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Abstract

This paper develops an adaptive nonsingular fast terminal sliding-mode control (ANFTSMC) scheme for the continuum robot subjected to uncertain dynamics, external disturbances, and input nonlinearities (e.g., actuator deadzones/faults). Concretely, a function approximation technique (FAT) is utilized to estimate unknown robot dynamics and actuator deadzones/faults online. Furthermore, a disturbance observer (DO) is devised to make up for unknown external disturbances. Then, an ANFTSMC scheme combined with FAT and DO is developed, to expedite the restoration of the stability for the continuum robot. The proposed ANFTSMC not only can retain the benefits of traditional terminal sliding-mode control (TSMC), containing easy enforcement, quick response, and robustness to uncertainties but also dispose of the latent singularity for traditional faster TSMC designs. Afterward, the simulation results show that the proposed controller can effectively improve the trajectory tracking accuracy of the continuum robot, and the tracking root-mean-square errors are 0.0115 and 0.0128 rad. Finally, the effectiveness of ANFTSMC scheme is validated by experiments.

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具有输入非线性和干扰的不确定连续机器人的自适应逼近滑模控制

本文针对不确定动态、外部干扰和输入非线性（如致动器死区/故障）的连续体机器人，开发了一种自适应非奇异快速终端滑模控制（ANFTSMC）方案。具体来说，利用函数逼近技术（FAT）来在线估计未知的机器人动力学和致动器死区/故障。此外，还设计了一个干扰观测器（DO）来弥补未知的外部干扰。然后，开发出一种与 FAT 和 DO 相结合的 ANFTSMC 方案，以加快连续机器人稳定性的恢复。所提出的 ANFTSMC 不仅保留了传统末端滑模控制（TSMC）的优点，包括易于执行、快速响应和对不确定性的鲁棒性，还消除了传统快速 TSMC 设计的潜在奇异性。随后，仿真结果表明，所提出的控制器能有效提高连续体机器人的轨迹跟踪精度，跟踪均方根误差分别为 0.0115 和 0.0128 rad。最后，实验验证了 ANFTSMC 方案的有效性。

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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来源期刊

Applied Bionics and Biomechanics ENGINEERING, BIOMEDICAL-ROBOTICS

自引率

4.50%

发文量

338

审稿时长

>12 weeks

期刊介绍： Applied Bionics and Biomechanics publishes papers that seek to understand the mechanics of biological systems, or that use the functions of living organisms as inspiration for the design new devices. Such systems may be used as artificial replacements, or aids, for their original biological purpose, or be used in a different setting altogether.