State-restricted adaptive control of a multilevel rotating electromagnetic mechanical flexible device using electromagnetic actuators.

Rafael Pérez-San Lázaro, Karen Jazmin Mendoza-Bautista, Rita Q Fuentes-Aguilar, Isaac Chairez
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Abstract

This work presents the development of a multilevel electromagnetic actuation system that controls the shape of a flexible rotatory robotic structure. An array of electromagnets is used as the set of actuators that regulate the position of permanent magnets within the flexible device. The primary outcome of this study is the design and experimental validation of the multilevel rotating device. In addition, the theoretical description of the system motion under electromagnetic actuation is formulated using Euler-Lagrange and electromagnetic theories. Given the developed model, a theoretical study leads to designing an adaptive control that considers motion restrictions in the flexible device. The controller aims to modify the current applied to the electromagnets, which changes the interaction forces between the electromagnet and the permanent magnets in the robotic flexible structure. A set of numerical simulations confirms the proposed controller's effectiveness compared to the traditional state feedback approach that does not consider the state restrictions, which is implemented in devices that also operate under an electromagnetic approach. Furthermore, an experimental version of the flexible device allows for testing of the developed controller. The experimental results show the suitability of the proposed control to generate non-oscillatory controlled motion during the regulation of the flexible mechanic device shape.

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使用电磁致动器的多级旋转电磁机械柔性装置的状态限制自适应控制。
本作品介绍了一种多级电磁致动系统的开发情况,该系统可控制柔性旋转机器人结构的形状。电磁阵列被用作一组执行器,用于调节柔性装置内永久磁铁的位置。本研究的主要成果是多级旋转装置的设计和实验验证。此外,还利用欧拉-拉格朗日和电磁理论对电磁致动下的系统运动进行了理论描述。根据所建立的模型,通过理论研究设计出一种考虑到柔性装置运动限制的自适应控制。该控制器旨在修改施加到电磁铁上的电流,从而改变机器人柔性结构中电磁铁和永久磁铁之间的相互作用力。与不考虑状态限制的传统状态反馈方法相比,一组数值模拟证实了所提出的控制器的有效性。此外,柔性设备的实验版本允许对开发的控制器进行测试。实验结果表明,在调节柔性机械装置形状的过程中,所提出的控制器适合产生非振荡受控运动。
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