具有五次非线性的 MEMS 谐振器模型研究

M. E. Abdelraouf, A. Kandil, W. K. Zahra, A. Elsaid
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引用次数: 0

摘要

微机电系统(MEMS)谐振器被广泛应用于时间基准、运动传感、信号过滤、质量检测等多个领域。本文旨在利用多尺度方法推导 MEMS 谐振器振动响应的分析公式。通过使用多尺度技术建立微梁的动力学模型,研究了复杂的非线性系统在各种交流和直流电压下的特性。测试了所得到的雅各布矩阵特征值,以验证这些解决方案的稳定性范围;从而解释了实验性能中出现的跳变现象。为了研究谐振器特性对这种梁的非线性动力学行为的影响,我们展示了几幅响应图。最后,使用四阶 Rung-Kutta 方法获得了数值解,以验证所研究模型的整体行为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation of a MEMS resonator model with quintic nonlinearity
Micro-electromechanical system (MEMS) resonator is decidedly utilized in a diversity of areas, including time referencing, movement sensing, signal filtration, mass detecting, and further numerous applications. The aim of this article is to use the multiple scales approach to derive analytical formulas for MEMS resonator vibration response. The properties of the complicated nonlinear system at various AC and DC voltages are investigated to be extremely well captured by modeling the dynamics of the micro-beam using multiple scales technique. The resulting Jacobian matrix eigenvalues are tested to verify the stability ranges of these solutions; hence, the jump phenomenon that occurs in experimental performance is interpreted. To study the influence of resonator characteristics on the nonlinear dynamical behavior of such a beam, several response plots are presented. Finally, a numerical solution is obtained with the fourth order Rung-Kutta method to verify the studied model’s overall behavior.
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