Design and application of models reference adaptive control (MRAC) on ball and beam

Journal of Mechatronics Electrical Power and Vehicular Technology Pub Date : 2022-07-29 DOI:10.14203/j.mev.2022.v13.15-23

M. Z. Romdlony, M. R. Rosa, Edwin Muhammad Puji Syamsudin, B. Trilaksono, Agung Surya Wibowo

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Abstract

This paper presents the implementation of an adaptive control approach to the ball and beam system (BBS). The dynamics of a BBS are non-linear, and in the implementation, the uncertainty of the system's parameters may occur. In this research, the linear state-feedback model reference adaptive control (MRAC) is used to synchronize the states of the BBS with the states of the given reference model. This research investigates the performance of the MRAC method for a linear system that is applied to a non-linear system or BBS. In order to get a faster states convergence response, we define the initial condition of the feedback gains. In addition, the feedback gains are limited to get less oscillation response. The results show the error convergence is improved for the different sets of the sinusoidal reference signal for the MRAC with modified feedback gains. The ball position convergence improvement of MRAC with modified feedback gains for sinusoidal reference with an amplitude of 0.25, 0.5, and 0.75 are 35.1 %, 36 %, and 52.4 %, respectively.

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球梁模型参考自适应控制(MRAC)的设计与应用

提出了一种球梁系统的自适应控制方法。BBS的动力学是非线性的，在实现过程中可能会出现系统参数的不确定性。在本研究中，使用线性状态反馈模型参考自适应控制(MRAC)来同步BBS的状态与给定参考模型的状态。本研究探讨了应用于非线性系统或BBS的线性系统的MRAC方法的性能。为了得到更快的状态收敛响应，我们定义了反馈增益的初始条件。此外，为了获得较小的振荡响应，还限制了反馈增益。结果表明，改进反馈增益后，不同正弦参考信号组的误差收敛性得到了改善。对于振幅为0.25、0.5和0.75的正弦参考信号，改进反馈增益后的MRAC球位收敛性提高分别为35.1%、36%和52.4%。

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Journal of Mechatronics Electrical Power and Vehicular Technology

CiteScore

0.70

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0.00%

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