Why active Willis metamaterials? A controllability and observability perspectivea).

IF 2.1 2区 物理与天体物理 Q2 ACOUSTICS
A Baz
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Abstract

Recently, active Willis metamaterials (AWM) have been the focus of extensive investigations because of their unique electro-elastic coupling characteristics. However, the treatments of this class of materials have been carried out exclusively, in all the available literature, by approaches that do not rely on solid control theory basis. In this paper, the emphasis is placed on revealing very important control features that are inherent to this class of materials because of their Willis coupling characteristics. These features lie in the enhanced controllability and observability properties of the AWM as compared to non-Willis active materials. Such control properties enable the AWM to possess broad sensing and actuation capabilities that can lend this material to be an effective means for monitoring and controlling the behavior of numerous critical applications, such as acoustic cloaking, particularly when integrated with appropriate robust control strategies. A simple example of a piezoelectric-based AWM is presented to demonstrate its effective control capabilities and distinguish this class of materials from conventional materials. In the selected example, the AWM is structured from two dissimilar masses connected by a piezoelectric spring. Lagrange dynamics formulation is utilized to generate the equations governing the Willis coupling, the piezoelectric coupling, and reveal the inherent control features. With this developed controlled-based structure of the AWM, it is shown that the AWM can simultaneously monitor and control both the strain and velocity whereas the conventional active material, which is formed from two similar masses connected by a piezoelectric spring, can only measure and control the strain alone. It is envisioned that the revealed control metrics for the simple one-dimensional AMW example can serve as means for investigating the potential of AMW's of higher dimensionality.

为什么要采用有源威利斯超材料?可控性和可观测性视角a).
最近,有源威利斯超材料(AWM)因其独特的电弹性耦合特性而成为广泛研究的焦点。然而,在所有现有文献中,对这一类材料的研究都是通过不依赖于坚实控制理论基础的方法进行的。本文的重点是揭示这类材料因其威利斯耦合特性而固有的非常重要的控制特性。与非威利斯活性材料相比,这些特点在于 AWM 的可控性和可观测性得到了增强。这种控制特性使 AWM 具备广泛的传感和致动能力,从而使这种材料成为监测和控制声隐形等众多关键应用行为的有效手段,尤其是在与适当的稳健控制策略相结合时。本文介绍了一个基于压电的 AWM 的简单示例,以展示其有效的控制能力,并将这一类材料与传统材料区分开来。在所选示例中,AWM 由压电弹簧连接的两个不同质量块构成。利用拉格朗日动力学公式生成了威利斯耦合和压电耦合方程,并揭示了固有的控制特性。研究表明,利用所开发的基于受控结构的 AWM,AWM 可以同时监测和控制应变和速度,而传统的活性材料(由压电弹簧连接的两个相似质量块组成)只能测量和控制应变。我们设想,针对简单的一维 AMW 例子所揭示的控制指标可以作为研究更高维 AMW 潜力的手段。
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
CiteScore
4.60
自引率
16.70%
发文量
1433
审稿时长
4.7 months
期刊介绍: Since 1929 The Journal of the Acoustical Society of America has been the leading source of theoretical and experimental research results in the broad interdisciplinary study of sound. Subject coverage includes: linear and nonlinear acoustics; aeroacoustics, underwater sound and acoustical oceanography; ultrasonics and quantum acoustics; architectural and structural acoustics and vibration; speech, music and noise; psychology and physiology of hearing; engineering acoustics, transduction; bioacoustics, animal bioacoustics.
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