单晶硅等高线模机电射频谐振器的有限元分析

C. Maxey, S. Raman
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引用次数: 3

摘要

微米级机电盘形谐振器的工作频率超过1千兆赫,在这些频率上的质量因数超过1500。此外,这种圆盘谐振器可以在当前的硅CMOS和BiCMOS集成电路工艺中实现,使其成为传统高q片外元件的有吸引力的替代品。这些器件的精确建模对于预测模态振型和最重要的振动频率至关重要。本文提出了一种基于有限元的圆盘形谐振器高阶效应建模方法。深入研究了不同尺寸的圆盘谐振器的模态振型,以及在不同位置附着在圆盘上的基板锚的影响。此外,还模拟了金属层(如化学镀铜)沉积在磁盘上对谐振器运行的影响。所有的模拟都是在一个完全耦合的机电环境中进行的,以便纳入尽可能多的过程和激励变量。
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Finite Element-Based Analysis of Single-Crystal Si Contour-Mode Electromechanical RF Resonators
Micron-scale electromechanical disk-shaped resonators have exhibited operational frequencies above 1 GHz and quality factors exceeding 1,500 at these frequencies. Additionally, such disk resonators can be potentially realized in current silicon CMOS and BiCMOS integrated circuit processes, making them attractive alternatives to traditional high-Q off-chip components. Accurate modeling of these devices is critical to predicting the mode-shape and, most importantly, the vibration frequency. This paper presents a finite element-based approach to modeling higher-order effects in disk-shaped resonators using ANSYS 7.0. An in-depth study of the mode-shapes for disk resonators of various sizes, and the effects of substrate anchors attached to the disks at various locations, is included. Effects on resonator operation due to metal layers, such as electroless plated copper, deposited on the disks are also simulated. All simulations are performed in a fully coupled electrical-mechanical environment so as to incorporate as many process and excitation variables as possible.
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