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基于结构 [公式:见正文] 的 looptune 和 LQR 对 4 自由度机器人机械手的性能比较。

Performance comparison of structured [Formula: see text] based looptune and LQR for a 4-DOF robotic manipulator.

机构信息

High Voltage and Short Circuit Laboratory, National Transmission and Despatch Company (NTDC), Rawat, Islamabad, Pakistan.

Department of Computer Science, National University of Technology (NUTECH), Islamabad, Pakistan.

出版信息

PLoS One. 2022 Apr 11;17(4):e0266728. doi: 10.1371/journal.pone.0266728. eCollection 2022.

DOI:10.1371/journal.pone.0266728
PMID:35404940
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9000114/
Abstract

We explore looptune, a MATLAB-based structured [Formula: see text] synthesis technique in the context of robotics. Position control of a 4 Degree of Freedom (DOF) serial robotic manipulator developed using Simulink is the problem under consideration. Three full state feedback control systems were developed, analyzed and compared for both steady-state and transient performance using the Linear Quadratic Regulator (LQR) and looptune. Initially, a single gain feedback controller was synthesized using LQR. This system was then modified by augmenting the state feedback controller with Proportional Integral (PI) and Integral regulators, thereby creating a second and third control system respectively. In both the second and third control systems, the LQR synthesized gain and additional gains were further tuned using looptune to achieve improvement in performance. The second and third systems were also compared in terms of tracking a time-dependent trajectory. Finally, the LQR and looptune synthesized controllers were tested for robustness by simultaneously increasing the mass of each manipulator link. In comparison to LQR, the second system consisting of Single Input Single Output (SISO) PI controllers and the state feedback matrix succeeded in meeting the control objectives in terms of performance, optimality, trajectory tracking, and robustness. The third system did not improve performance in contrast to LQR, but still showed robustness under mass variation. In conclusion, our results have shown looptune to have a comparatively better performance over LQR thereby highlighting its promising potential for future emerging control system applications.

摘要

我们探讨了 looptune,一种基于 MATLAB 的结构化[公式:见正文]合成技术在机器人学中的应用。考虑的问题是使用 Simulink 开发的 4 自由度(DOF)串联机器人操纵器的位置控制。为了稳态和瞬态性能,使用线性二次调节器(LQR)和 looptune 开发、分析和比较了三个全状态反馈控制系统。最初,使用 LQR 合成了一个单增益反馈控制器。然后,通过在状态反馈控制器中增加比例积分(PI)和积分调节器来修改该系统,从而分别创建了第二个和第三个控制系统。在第二个和第三个控制系统中,使用 looptune 进一步调整 LQR 合成的增益和附加增益,以提高性能。还比较了第二个和第三个控制系统在跟踪时变轨迹方面的性能。最后,通过同时增加每个操纵器连杆的质量来测试 LQR 和 looptune 合成的控制器的鲁棒性。与 LQR 相比,由单输入单输出(SISO)PI 控制器和状态反馈矩阵组成的第二个系统在性能、最优性、轨迹跟踪和鲁棒性方面成功地满足了控制目标。与 LQR 相比,第三个系统的性能没有提高,但在质量变化下仍表现出鲁棒性。总之,我们的结果表明 looptune 相对于 LQR 具有更好的性能,从而突出了其在未来新兴控制系统应用中的广阔前景。

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