Localization in coupled systems: Part II — Consideration on damping issue in a mode-localized cantilever array

2017 Symposium on Design, Test, Integration and Packaging of MEMS/MOEMS (DTIP) Pub Date : 2017-05-01 DOI:10.1109/DTIP.2017.7984503

Xiaodong Li, Di Zhou, R. Liu, Shuyi Liu, Xin Liu, Dong F. Wang

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引用次数: 4

Abstract

The use of vibration mode localization in arrays of mechanically-coupled, nearly identical cantilevers has been studied for ultra-sensitive mass detection and analyte identification. The effects of geometrical design of the coupling overhang, cantilever length, as well as the number of identical coupled cantilevers on the magnitude enhancement with a small mass perturbation were previously reported in DTIP 2011. This paper however, analytically investigates the effect of material damping, induced by the internal friction loss, on energy confinement in a mode-localized three-cantilever array. Firstly, the material damping will not change three typical eigenstates of the array. Therefore, the proposed three-cantilever array can be applied to mass detection and analyte identification as well. Secondly, the sensitivity of mass sensing with the proposed array declined from 22990.70 to 33.56 because of the decrease in amplitude values caused by energy loss. It is the material damping that brings about the energy loss that influences the spatial propagation confinement of vibration. Additionally, experimental verification will be conducted in our future work.

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耦合系统的局部化:第二部分-模态局部化悬臂阵列阻尼问题的思考

利用振动模态定位在机械耦合阵列中，几乎相同的悬臂梁已经研究了超灵敏的质量检测和分析物鉴定。先前在DTIP 2011中报道了耦合悬挑的几何设计、悬臂长度以及相同耦合悬臂的数量对小质量摄动的幅度增强的影响。然而，本文分析研究了由内摩擦损失引起的材料阻尼对模式局域化三悬臂阵列能量约束的影响。首先，材料阻尼不会改变阵列的三个典型特征态。因此，所提出的三悬臂阵列也可以应用于质量检测和分析物鉴定。其次，由于能量损失导致振幅值下降，该阵列的质量传感灵敏度从22990.70下降到33.56;材料阻尼带来的能量损失影响着振动的空间传播限制。此外，我们将在未来的工作中进行实验验证。

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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2017 Symposium on Design, Test, Integration and Packaging of MEMS/MOEMS (DTIP)

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