A New Z-axis Resonant Micro-Accelerometer Based on Electrostatic Stiffness

Yang, Bo; Wang, Xingjun; Dai, Bo; Liu, Xiaojun

doi:10.3390/s150100687

Cited by 26 publications

(15 citation statements)

References 14 publications

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“…Furthermore, two opposite feedback voltages

are applied to the two fixed capacitor plates to generate a difference of potential between the proof mass and the fixed plates, in order to restore the proof mass to its null position. Those voltages would contribute to an electrostatic field between the proof mass and the fixed plates, and yield an electrostatic feedback force on the proof mass [ 21 , 22 , 23 , 24 ]:

where

is the root mean square (RMS) value of the pumping voltage

. The first item in Equation (4) is the effective electrostatic feedback force, and hence the output acceleration can be written as

…”

Section: Structure Design and Noise Analysis Of The Electrostatic mentioning

confidence: 99%

A Subnano-g Electrostatic Force-Rebalanced Flexure Accelerometer for Gravity Gradient Instruments

Yan

Xie

Zhang

et al. 2017

Sensors

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A subnano-g electrostatic force-rebalanced flexure accelerometer is designed for the rotating accelerometer gravity gradient instrument. This accelerometer has a large proof mass, which is supported inversely by two pairs of parallel leaf springs and is centered between two fixed capacitor plates. This novel design enables the proof mass to move exactly along the sensitive direction and exhibits a high rejection ratio at its cross-axis directions. Benefiting from large proof mass, high vacuum packaging, and air-tight sealing, the thermal Brownian noise of the accelerometer is lowered down to less than 0.2 ng/Hz with a quality factor of 15 and a natural resonant frequency of about 7.4 Hz. The accelerometer’s designed measurement range is about ±1 mg. Based on the correlation analysis between a commercial triaxial seismometer and our accelerometer, the demonstrated self-noise of our accelerometers is reduced to lower than 0.3 ng/Hz over the frequency ranging from 0.2 to 2 Hz, which meets the requirement of the rotating accelerometer gravity gradiometer.

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“…Furthermore, two opposite feedback voltages

where

is the root mean square (RMS) value of the pumping voltage

. The first item in Equation (4) is the effective electrostatic feedback force, and hence the output acceleration can be written as

…”

Section: Structure Design and Noise Analysis Of The Electrostatic mentioning

confidence: 99%

A Subnano-g Electrostatic Force-Rebalanced Flexure Accelerometer for Gravity Gradient Instruments

Yan

Xie

Zhang

et al. 2017

Sensors

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“…The torsional movement is converted into a frequency variation by the resonator and the electrostatic coupling combs [15]. The relationship between the moment and the frequency is:

f \approx f_{0} + S M

where S is the sensitivity coefficient from the moment to the frequency and:

S = \frac{n ε L V^{2} B}{4 π^{2} f_{0} d_{1}^{3} m_{r} k_{o}}

where n is the number of coupling combs, L is the length of coupling combs, V is the bias voltage applied on the coupling combs, B is the equivalent distance from the electrostatic coupling combs to the z -axis (shown in Figure 1A), d 1 is the coupling combs gap and d 1 << d 2 , m r is the proof mass of resonator, f 0 is the static frequency of the resonator and:

f_{0} = \frac{1}{2 π} \sqrt{\frac{(k_{r} - \frac{2 n ε L V^{2} H}{d_{1}^{3}})}{m_{r}}}

where k r is the stiffness of resonator and H is the comb thickness.…”

Section: Device Description and Designmentioning

confidence: 99%

Design and Analysis of a New Hair Sensor for Multi-Physical Signal Measurement

Yang

2016

Sensors

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Abstract:A new hair sensor for multi-physical signal measurements, including acceleration, angular velocity and air flow, is presented in this paper. The entire structure consists of a hair post, a torsional frame and a resonant signal transducer. The hair post is utilized to sense and deliver the physical signals of the acceleration and the air flow rate. The physical signals are converted into frequency signals by the resonant transducer. The structure is optimized through finite element analysis. The simulation results demonstrate that the hair sensor has a frequency of 240 Hz in the first mode for the acceleration or the air flow sense, 3115 Hz in the third and fourth modes for the resonant conversion, and 3467 Hz in the fifth and sixth modes for the angular velocity transformation, respectively. All the above frequencies present in a reasonable modal distribution and are separated from interference modes. The input-output analysis of the new hair sensor demonstrates that the scale factor of the acceleration is 12.35 Hz/g, the scale factor of the angular velocity is 0.404 nm/deg/s and the sensitivity of the air flow is 1.075 Hz/(m/s) 2 , which verifies the multifunction sensitive characteristics of the hair sensor. Besides, the structural optimization of the hair post is used to improve the sensitivity of the air flow rate and the acceleration. The analysis results illustrate that the hollow circular hair post can increase the sensitivity of the air flow and the II-shape hair post can increase the sensitivity of the acceleration. Moreover, the thermal analysis confirms the scheme of the frequency difference for the resonant transducer can prominently eliminate the temperature influences on the measurement accuracy. The air flow analysis indicates that the surface area increase of hair post is significantly beneficial for the efficiency improvement of the signal transmission. In summary, the structure of the new hair sensor is proved to be feasible by comprehensive simulation and analysis.

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“…Micromechanical resonant accelerometers have been widely used in high-precision measurement applications because of their distinctive advantages, such as direct frequency signal output, high sensitivity, stable performance and high resolution [1][2][3]. Microlever mechanisms, including single-stage and multi-stage, are very useful in micromechanical devices in order to transfer an input force/displacement to an output to achieve mechanical and structural improvement.…”

Section: Introductionmentioning

confidence: 99%

Design of a new differential silicon resonant accelerometer with dual proofmasses using two-stage microlever

Wen

Fan

et al. 2015

2015 Ieee Sensors

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A novel micromechanical silicon resonant accelerometer using a two-stage microlever and dual-proofmass architecture is presented. Based on the structural model of the accelerometer, the ANSYS simulations are performed to investigate the effects of sensitive structural parameters on the acceleration sensitivity and operating frequency of accelerometer, and the sensitivity change in response to temperature acclimation. The results show that the proposed accelerometer achieves a sensitivity of 150 Hz/g and a linear accuracy of 1.91‰ with a nominal frequency of 22482 Hz in the dynamic range of ±50 g. Moreover, in addition to doubling the sensitivity, the introduced two-proofmass structure enables to cancel the lock-in phenomenon existing in a double-ended tuning fork resonator, in contrast with a monolithic proofmass structure.

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A New Z-axis Resonant Micro-Accelerometer Based on Electrostatic Stiffness

Cited by 26 publications

References 14 publications

A Subnano-g Electrostatic Force-Rebalanced Flexure Accelerometer for Gravity Gradient Instruments

A Subnano-g Electrostatic Force-Rebalanced Flexure Accelerometer for Gravity Gradient Instruments

Design and Analysis of a New Hair Sensor for Multi-Physical Signal Measurement

Design of a new differential silicon resonant accelerometer with dual proofmasses using two-stage microlever

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