将 Q 值与 TCF 连接，用于 MEMS 和压电谐振器

arXiv - PHYS - Classical Physics Pub Date : 2024-07-12 DOI:arxiv-2407.09455

S. McHugh

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引用次数: 0

摘要

任何 MEMS 谐振器都有两个关键特性，即品质因数（Q 值）和频率温度系数（TCF 值）。这里通过一个现象学非谐波振荡器模型证明了 Q 值和 TCF 值之间的联系。具体地说，它表明对 $TCF$ 负责的相同非线性项对谐振器的 $Q$ 设置了上限。我们找到了一个简洁的公式来估算这一损失，并证明它与伍德拉夫的阿基泽阻尼公式密切相关。最后，将该模型应用于已公布的 AlN-on-diamond 压电谐振器数据。这里的重点是 MEMS 谐振器，但该方法应广泛适用于任何具有非零 TCF$ 的谐振。

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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Connecting Q to TCF for MEMS and piezoelectric resonators

Two critical characteristics for any MEMS resonator are the quality factor ($Q$) and the temperature coefficient of frequency ($TCF$). The connection between $Q$ and $TCF$ is demonstrated here with a phenomenological anharmonic oscillator model. Specifically, it is shown that the same nonlinear terms responsible for the $TCF$ set an upper limit on the resonator's $Q$. A concise formula is found to estimate this loss and is shown to be closely related to Woodruff's formula for Akhiezer damping. The use of this formula is illustrated by extending the model to an important class of MEMS; piezoelectric resonators. Finally, the model is applied to published data for an AlN-on-diamond piezoelectric resonator. The focus here is on MEMS resonators, but the method should apply broadly to any resonance with non-zero $TCF$.

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arXiv - PHYS - Classical Physics

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