J. Giner scite author profile

This letter presents the design, fabrication, and demonstration of a CMOS-MEMS filter based on two high-Q submicrometer-scale clamped-clamped beam resonators with resonance frequency around 22 MHz. The MEMS resonators are fabricated with a 0.35-μm CMOS process and monolithically integrated with an on-chip differential amplifier. The CMOS-MEMS resonator shows high-quality factors of 227 in air conditions and 4400 in a vacuum for a bias voltage of 5 V. In air conditions, the CMOS-MEMS parallel filter presents a programmable bandwidth from 100 to 200 kHz with a < 1-dB ripple. In a vacuum, the filter presents a stop-band attenuation of 37 dB and a shape factor as low as 2.5 for a CMOS-compatible bias voltage of 5 V, demonstrating competitive performance compared with the state of the art of not fully integrated MEMS filters. Index Terms-Bandpass filter, CMOS-MEMS, micromechanical filter, system-on-chip.

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Integration of RF-MEMS resonators on submicrometric commercial CMOS technologies

Lopez

Verd²,

Teva

et al. 2008

J. Micromech. Microeng.

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Integration of electrostatically driven and capacitively transduced MEMS resonators in commercial CMOS technologies is discussed. A figure of merit to study the performance of different structural layers and different technologies is defined. High frequency (HF) and very high frequency (VHF) resonance MEMS metal resonators are fabricated on a deep submicron 0.18 μm commercial CMOS technology and are characterized using electrical tests without amplification, demonstrating the applicability of the MEMS fabrication process for future technologies. Moreover, the fabricated devices show comparable performance in terms of Q × f res with previously presented MEMS resonators, whereas the small gap allows obtaining a low motional resistance with a single resonator approach.

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Exploitation of non-linearities in CMOS-NEMS electrostatic resonators for mechanical memories

Uranga

Verd

Marigo

et al. 2013

Sensors and Actuators A: Physical

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Integration of NEMS resonators in a 65nm CMOS technology

Munoz-Gamarra

Alcaine

Marigo

et al. 2013

Microelectronic Engineering

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MEMS Gyroscope With Concentrated Springs Suspensions Demonstrating Single Digit Frequency Split and Temperature Robustness

Giner

Maeda

Ono

et al. 2019

J. Microelectromech. Syst.

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J. Giner

A CMOS–MEMS RF-Tunable Bandpass Filter Based on Two High- $Q$ 22-MHz Polysilicon Clamped-Clamped Beam Resonators

Integration of RF-MEMS resonators on submicrometric commercial CMOS technologies

Exploitation of non-linearities in CMOS-NEMS electrostatic resonators for mechanical memories

Integration of NEMS resonators in a 65nm CMOS technology

MEMS Gyroscope With Concentrated Springs Suspensions Demonstrating Single Digit Frequency Split and Temperature Robustness

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