Vibrating RF MEMS for Low Power Communications

Nguyen, C.T.-C.

doi:10.1557/proc-741-j12.1

Cited by 11 publications

(12 citation statements)

References 23 publications

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“…Though designers currently use quartz, ceramic, and surfaceacoustic wave devices, surface-micromachined microelectromechanical system resonators (MEMS resonators) in development offer an attractive alternative. Because they can be integrated into standard complementary metal-oxide semiconductor (CMOS) technology, MEMS resonators have the potential to use less area and power, and cost less money than existing commercial devices [1]. But to be viable, energy losses in these MEMS resonators must be minimized.…”

Section: Introductionmentioning

confidence: 99%

“…But to be viable, energy losses in these MEMS resonators must be minimized. The usual measure of this energy loss is the quality factor Q of a resonant peak, defined as Q = 2 Stored energy Energy lost per period (1) For an ideal linear single degree of freedom oscillator Q = | |/2 Im[ ], where is the oscillator's complex-valued eigenvalue [2, p. 158]. Resonators in cell phone filters, for example, require Q values greater than 1000 for good performance, and higher values are preferable [1,3].…”

Section: Introductionmentioning

confidence: 99%

“…The usual measure of this energy loss is the quality factor Q of a resonant peak, defined as Q = 2 Stored energy Energy lost per period (1) For an ideal linear single degree of freedom oscillator Q = | |/2 Im[ ], where is the oscillator's complex-valued eigenvalue [2, p. 158]. Resonators in cell phone filters, for example, require Q values greater than 1000 for good performance, and higher values are preferable [1,3]. Depending on scale, geometry, and materials, the energy losses that lower Q may come from material damping, air damping, thermoelastic damping, or radiation of elastic waves from an anchor [4].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Elastic PMLs for resonator anchor loss simulation

Bindel

Govindjee

2005

Numerical Meth Engineering

146

104

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SUMMARYElectromechanical resonators and filters, such as quartz, ceramic, and surface-acoustic wave devices, are important signal-processing elements in communication systems. Over the past decade, there has been substantial progress in developing new types of miniaturized electromechanical resonators using microfabrication processes. For these micro-resonators to be viable they must have high and predictable quality factors (Q). Depending on scale and geometry, the energy losses that lower Q may come from material damping, thermoelastic damping, air damping, or radiation of elastic waves from an anchor. Of these factors, anchor losses are the least understood because such losses are due to a complex radiation phenomena in a semi-infinite elastic half-space. Here, we describe how anchor losses can be accurately computed using an absorbing boundary based on a perfectly matched layer (PML) which absorbs incoming waves over a wide frequency range for any non-zero angle of incidence. We exploit the interpretation of the PML as a complex-valued change of co-ordinates to illustrate how one can come to a simpler finite element implementation than was given in its original presentations. We also examine the convergence and accuracy of the method, and give guidelines for how to choose the parameters effectively. As an example application, we compute the anchor loss in a micro disk resonator and compare it to experimental data. Our analysis illustrates a surprising mode-mixing phenomenon which can substantially affect the quality of resonance.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Elastic PMLs for resonator anchor loss simulation

Bindel

Govindjee

2005

Numerical Meth Engineering

146

104

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“…For RF engineers using quartz, ceramic, and surface acoustic wave devices, surface-micromachined MEMS resonators in development offer an attractive alternative. Because they can be integrated into CMOS, MEMS resonators have the potential to cost less area, power, and money than existing alternatives [10]. Such integrated high-frequency filters could qualitatively change the design of cell phones, making it possible to build a cheap phone to work with multiple networks operating at different carrier frequencies, and lowering power and size constraints to the point that inexpensive "Dick Tracy" watch phones could be a reality.…”

Section: Introductionmentioning

confidence: 99%

Model Reduction for RF MEMS Simulation

Bindel

Bai

Demmel

2006

Applied Parallel Computing. State of the Art in Scientific Computing

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Abstract. Radio-frequency (RF) MEMS resonators, integrated into CMOS chips, are of great interest to engineers planning the next generation of communication systems. Fast simulations are necessary in order to gain insights into the behavior of these devices. In this paper, we discuss two structure-preserving model-reduction techniques and apply them to the frequency-domain analysis of two proposed MEMS resonator designs.

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“…This requires small geometries which are conveniently provided by modern lithographic techniques. Among future applications of mechanical high-frequency resonators are ultrasensitive sensors for chemical or biological species [1,2] but also filters and other RF applications [3,4] that would benefit from the integration of active and passive components on the same chip.…”

Section: Introductionmentioning

confidence: 99%