Control Architectures for Metamaterials in Vibration Control

2023 IEEE International Conference on Mechatronics (ICM) Pub Date : 2023-03-15 DOI:10.1109/ICM54990.2023.10101931

V. F. Buskes, M. Kaczmarek, J. C. Veenstra, C. Coulais, S. Hosseinnia

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Abstract

Metamaterials are artificial structures with properties that are rare or non-existent in nature. These properties are created by the geometry and interconnection of the metamaterial unit cells. In active metamaterials, sensors and actuators are embedded in each unit cell to achieve greater design freedom and tunability of properties after the fabrication. While active metamaterials have been used in vibration control applications, the influence of applied control architectures on damping performance has not been thoroughly studied yet. This paper discusses the relationship between suitable control architectures for increased damping in finite active metamaterials and the number of damped modes. A metamaterial beam consisting of links with measured and actuated joints is considered. Optimal controllers for each of the considered scenarios are designed in the modal domain using linear-quadratic regulator (LQR). We show that, when all modes of a structure should be damped, the optimal solution can be reduced to a decentralised controller. When modes in a smaller range of frequencies are targeted, distributed controllers show better performance. The results are confirmed with experiments.

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振动控制中超材料的控制体系

超材料是一种人造结构，具有自然界中罕见或不存在的特性。这些特性是由超材料单元细胞的几何形状和互连产生的。在活性超材料中，传感器和致动器嵌入到每个单元中，以实现更大的设计自由度和制造后性能的可调性。虽然活性超材料已用于振动控制应用，但应用控制体系对阻尼性能的影响尚未得到深入研究。本文讨论了有限活性超材料中适当的增加阻尼控制体系与阻尼模态数目之间的关系。研究了一种由测量关节和驱动关节组成的超材料梁。采用线性二次型调节器(LQR)在模态域设计了每种情况下的最优控制器。我们表明，当结构的所有模态都需要阻尼时，最优解可以简化为分散控制器。当目标频率范围较小时，分布式控制器表现出更好的性能。实验结果证实了这一结论。

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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2023 IEEE International Conference on Mechatronics (ICM)

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