Add to ORKGIn this paper, we report on the design of a low power CMOS oscillator front-end interface circuit for micromachined resonant sensors. The circuits are fabricated in a standard 0.35 μm process while the MEMS resonators are fabricated in a SOI-MEMS foundry process with the two die electrically integrated through wirebonding in a ceramic package. The oscillator core draws less than 1μA at 1.2V supply while demonstrating a short-term frequency stability of less than 0.5 ppm
This article presents a 6.89 MHz MEMS oscillator based on an ultra-low-power, low-noise, tunable gai...
This paper describes a technical approach toward the realization of a low-power temperature-compensa...
This paper presents an overview of micro electromechanical (MEMS) based oscillators. The accuracy an...
This paper reports on the design and implementation of a low power MEMS oscillator based on capaciti...
We present the design of an integrated electronic oscillator aimed at the detection of the response ...
Resonant mass sensors (i.e. microbalances) are commonly used in chemical and biochemical sensing, an...
A 180-nm gap micromechanical resonator biased at 20 V and full custom integrated electronics are use...
This paper focuses on the design and development of a CMOS-MEMS resonator integrated with an on-chip...
AbstractThis paper shows the results of fabrication and characterization of a CMOS oscillator with a...
This paper presents the design, fabrication, and electrical characterization of an electrostatically...
This paper describes a technical approach toward the realization of a low-power temperature-compensa...
This paper presents an ultra-low power, silicon-integrated readout for resonant MEMS strain sensors...
We present the design and analysis result of a low power, low noise, 20 MHz CMOS-MEMS oscillators. T...
Abstract — A completely monolithic high-Q oscillator, fabri-cated via a combined CMOS plus surface m...
Electronic oscillators using an electromechanical device as a frequency reference are irreplaceable ...
This article presents a 6.89 MHz MEMS oscillator based on an ultra-low-power, low-noise, tunable gai...
This paper describes a technical approach toward the realization of a low-power temperature-compensa...
This paper presents an overview of micro electromechanical (MEMS) based oscillators. The accuracy an...
This paper reports on the design and implementation of a low power MEMS oscillator based on capaciti...
We present the design of an integrated electronic oscillator aimed at the detection of the response ...
Resonant mass sensors (i.e. microbalances) are commonly used in chemical and biochemical sensing, an...
A 180-nm gap micromechanical resonator biased at 20 V and full custom integrated electronics are use...
This paper focuses on the design and development of a CMOS-MEMS resonator integrated with an on-chip...
AbstractThis paper shows the results of fabrication and characterization of a CMOS oscillator with a...
This paper presents the design, fabrication, and electrical characterization of an electrostatically...
This paper describes a technical approach toward the realization of a low-power temperature-compensa...
This paper presents an ultra-low power, silicon-integrated readout for resonant MEMS strain sensors...
We present the design and analysis result of a low power, low noise, 20 MHz CMOS-MEMS oscillators. T...
Abstract — A completely monolithic high-Q oscillator, fabri-cated via a combined CMOS plus surface m...
Electronic oscillators using an electromechanical device as a frequency reference are irreplaceable ...
This article presents a 6.89 MHz MEMS oscillator based on an ultra-low-power, low-noise, tunable gai...
This paper describes a technical approach toward the realization of a low-power temperature-compensa...
This paper presents an overview of micro electromechanical (MEMS) based oscillators. The accuracy an...