Resonant Pressure Micro Sensors Based on Dual Double Ended Tuning Fork Resonators

Lu, Yulan; Zhang, Sen; Yan, Pengxun; Li, Yadong; Yu, Jie; Chen, Deyong; Wang, Junbo; Xie, Bin; Chen, Jian

doi:10.3390/mi10090560

Cited by 7 publications

(3 citation statements)

References 22 publications

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“…Figure 3(a) shows the fabrication process, which closely aligns with our previous works [13,14] but with a few innovative additions (Figure 3 (a v-vii)). The main difference was that a silicon wafer was utilized as an isolation layer.…”

Section: Fabricationsupporting

confidence: 81%

Stress isolations for resonant pressure micro sensors

Lu,

Xie,

Chen

et al. 2024

J. Phys.: Conf. Ser.

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This paper presents stress isolations for resonant pressure micro sensors that are supported by fixed isolation layers during assembly. While the resonant frequencies of the two resonators experience shifts due to measured pressures, they are susceptible to environmental perturbations. The proposed stress-isolated assembly in this study effectively mitigates the adverse effects of environmental noise and stabilizes the intrinsic frequencies of the resonators. Specifically, when subjected to temperature variations within the range of -55∼85 °C, the accuracy of the stress-isolated resonant pressure microsensor was determined to be ±0.01% FS. Similarly, during 3-axis random vibration tests, the accuracy of these stress-isolated resonant pressure microsensors was quantified as ±0.01% FS in response to environmental vibrations.

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Section: Fabricationsupporting

confidence: 81%

Stress isolations for resonant pressure micro sensors

Lu,

Xie,

Chen

et al. 2024

J. Phys.: Conf. Ser.

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“…Therefore, a smaller width rather than height is chosen in the structure design. Based on the resonant beam parameters and resonant frequencies of the existing structures [10,11,14], a resonant beam structure with a length of 1200 µm, a width of 20 µm, and a height of 40 µm is selected with an intrinsic frequency of 120 kHz. Preliminary structural models have been established, and dynamic analysis of the structure has been conducted using COMSOL.…”

Section: Resonant Beam Structural Analysis and Designmentioning

confidence: 99%

Design and Optimization of MEMS Resonant Pressure Sensors with Wide Range and High Sensitivity Based on BP and NSGA-II

Lv,

Li,

Miao

et al. 2024

Micromachines

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With the continuous progress of aerospace, military technology, and marine development, the MEMS resonance pressure sensor puts forward the requirements of not only a wide range but also high sensitivity. However, traditional resonators are hardly compatible with both. In response, we propose a new sensor structure. By arranging the resonant beam and the sensitive diaphragm vertically in space, the new structure improves the rigidity of the diaphragm without changing the thickness of the diaphragm and achieves the purpose of increasing the range without affecting the sensitivity. To find the optimal structural parameters for the sensor sensitivity and range, and to prevent the effects of modal disturbances, we propose a multi-objective optimization design scheme based on the BP and NSGA-II algorithms. The optimization of the structure parameters not only improved the sensitivity but also increased the interference frequency to solve the issue of mode interference. The optimized structure achieves a sensitivity and range of 4.23 Hz/kPa and 1–10 MPa, respectively. Its linear influence factor is 38.07, significantly higher than that of most resonant pressure sensors. The structural and algorithmic optimizations proposed in this paper provide a new method for designing resonant pressure sensors compatible with a wide range and high sensitivity.

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“…[1][2][3], industrial equipment [4], human-machine interfaces [5,6], wearable electronics [7], and robotics [8,9]. In recent years, studies on the operating mechanism of miniature pressure sensors have focused on piezoresistive [10][11][12][13][14][15][16], piezoelectric [17,18], resonant [19,20], fiber optic [21], and capacitive sensors [22]. Among them, capacitive miniature pressure sensor has the advantages of high resolution, high stability, and low energy consumption (table S1) [22][23][24][25][26][27], making it an ideal choice for miniature region pressure detection [28,29].…”

Section: Introductionmentioning

confidence: 99%

Wide-range, durable, and adaptable miniature pressure sensor based on planar capacitance

Liu,

Yuan,

Yang

et al. 2024

Smart Mater. Struct.

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Capacitive pressure sensor (CPS) is widely used in the field of industrial equipment, because of the merits of fast dynamic response and high resolution. However, the traditional laminated CPS makes it difficult to achieve a wide detection limit in a small size, and this structure is susceptible to electromagnetic interference. Here we developed a miniature planar capacitive pressure sensor (MPCPS) with high performance, which can realize the response to external touching stimuli through the deformation of the packaging material and the change of the equivalent resistance. A metal shielding layer was added under the insulating substrate to effectively isolate the external interference. The thickness of the sensor is about 200 μm, and the diameter of the core sensing area is less than 1 mm. Two types of electrodes with different shapes were designed, among which the spiral electrode MPCPS has better performance than the linear electrode MPCPS. The spiral electrode MPCPS has a high sensitivity of 99.2% MPa-1 in the low-pressure range (0 ~ 0.1 MPa), fast response (20 ms), wide detection limit (>1 MPa), and high durability (>2000 cycles). In addition, MPCPS is proven to have good resistance to high temperature and oil contamination. Finally, practical applications such as contact pressure measuring on the meshing surface of spur gears and mechanical gripper clamping force monitoring were successfully demonstrated. These results shed light on the potential application of the MPCPS in the pressure detection of industrial equipment.

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Resonant Pressure Micro Sensors Based on Dual Double Ended Tuning Fork Resonators

Cited by 7 publications

References 22 publications

Stress isolations for resonant pressure micro sensors

Stress isolations for resonant pressure micro sensors

Design and Optimization of MEMS Resonant Pressure Sensors with Wide Range and High Sensitivity Based on BP and NSGA-II

Wide-range, durable, and adaptable miniature pressure sensor based on planar capacitance

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