High-q integrated CMOS-MEMS resonators with deep-submicron gaps

2010 IEEE International Frequency Control Symposium Pub Date : 2010-06-01 DOI:10.1109/FREQ.2010.5556316

Wen-Chien Chen, Ming-Huang Li, W. Fang, Sheng-Shian Li

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引用次数: 9

Abstract

Integrated CMOS-MEMS free-free beam resonators using pull-in mechanism to surmount the limitation of CMOS minimum feature size and hence achieve deep-submicron electro-to-resonator gap spacing have been demonstrated to overcome Q-degradation and frequency variation caused by modulated boundary conditions, greatly improving resonator Q and at the same time reducing motional impedance to allow direct measurement without the use of readout circuitry. The key to attaining high Q and to stabilizing resonance frequency of resonators is to effectively decouple the pull-in scheme and mechanical boundary conditions of resonators. In this work, CMOS-MEMS resonators with deep-submicron gaps have been measured with motional impedance down to 172kΩ and Q's greater than 2,000. In addition, such a resonator monolithically integrated with CMOS amplifier, totally occupying die area of only 300µm × 130µm, was also tested with enhanced transmission. With such improved performance, this technique may pave a way to realize fully-integrated CMOS-MEMS oscillators, therefore benefitting future single-chip applications.

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深亚微米间隙的高q集成CMOS-MEMS谐振器

集成的CMOS- mems自由-自由光束谐振器使用拉入机制克服了CMOS最小特征尺寸的限制，从而实现了深亚微米的电-谐振器间隙间距，克服了调制边界条件引起的Q退化和频率变化，大大提高了谐振器Q，同时降低了运动阻抗，允许直接测量而不使用读出电路。实现谐振器高Q值和稳定谐振频率的关键是有效解耦谐振器的拉入方案和力学边界条件。在这项工作中，已经测量了具有深亚微米间隙的CMOS-MEMS谐振器，其运动阻抗低至172kΩ， Q大于2000。此外，该谐振器与CMOS放大器单片集成，整个芯片面积仅为300µm × 130µm，并进行了增强传输的测试。由于性能的提高，该技术可能为实现完全集成的CMOS-MEMS振荡器铺平道路，从而有利于未来的单芯片应用。

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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2010 IEEE International Frequency Control Symposium

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