Design of a Biaxial High-G Piezoresistive Accelerometer with a Tension–Compression Structure
Abstract
:1. Introduction
2. Sensor Analysis and Design
2.1. Tension–Compression Measurement Mechanism
2.2. Sensor Design
2.3. Test Circuit
3. Simulation Analysis
3.1. Modal Analysis
3.2. Harmonic Response Analysis
3.3. Sensitivity Analysis
4. Process Flow and Packaging Scheme
4.1. Process Flow
- (1)
- SOI wafers: SOI material is used, with single-crystal silicon material on the top and bottom layers and a silicon dioxide layer in the middle. SOI material has the advantages of high-temperature resistance and low-power consumption, which can meet the special requirements for aerospace, aviation, and explosion impact.
- (2)
- Deep reactive ion etching (DRIE): DRIE is performed on both sides of the wafer to form a distributed mass block structure.
- (3)
- Surface growth of silicon dioxide: Thermal oxidation is used to generate a silicon dioxide layer as an insulating layer for the subsequent processing of the resistor.
- (4)
- Production of P− and P+: In the first lithography step, boron ions are injected to form a P-type heavily doped region, which is the ohmic contact. In the second lithography step, boron ions are injected to form a P-type lightly doped region, which is the resistor.
- (5)
- Surface growth of silicon nitride: A 100 nm silicon nitride layer is formed on the surface using low-pressure chemical vapor deposition technology to protect the processed resistor.
- (6)
- Production of contact holes, wire leads, and pads: In order to connect the resistor to the chip surface, a third lithography step is performed to create contact holes at the base of the resistor. The boundary of the contact hole should be 2 μm smaller than that of the resistor strip. A 1 μm thick aluminum film is sputtered on the surface using PVD, and aluminum electrodes and pads are formed by lithography, followed by 30 min of metallization at 500 °C.
- (7)
- Inductively coupled plasma (ICP): ICP etching is performed on the front of the silicon wafer to release the structure.
- (8)
- Silicon–glass bonding technology: The silicon wafer and glass are bonded on a 300 μm thick Pyrex 7740 glass, with a bonding depth of 20 μm, forming an isolation and protective layer for the sensor chip.
4.2. Packaging Scheme
- Chip bonding
- 2.
- Lead bonding
- 3.
- Packaging scheme
5. Conclusions
- (1)
- The stress variation characteristics of the deformation of a cantilever beam under tension–compression are studied to determine the sensor’s sensitive structure. A test circuit resistant to cross-interference is designed to enhance measurement accuracy.
- (2)
- Modal analysis, harmonic response analysis, and sensitivity analysis of the designed high-g biaxial accelerometer are carried out using finite element analysis. The results show that the sensor has a range of 200,000 g, a minimum natural frequency of 112.83 kHz, and resonance frequencies of 509.8 kHz and 510.23 kHz in the X and Y directions, respectively. A relationship model between the output voltage and the acceleration of the sensor is established using MATLAB, with a measurement sensitivity of 1.39 µV/g in the X direction and 1.42 µV/g in the Y direction.
- (3)
- The process flow of the sensor is developed, with key process steps including photo etching, ion implantation, metal sputtering, thin film deposition, release structuring, and silicon–glass bonding. The chip is then bonded using an adhesive, and wire bonding was completed using a hot ultrasonic gold-wire-ball bonding method. Finally, the sensor chip is packaged using the combination of a metal casing and PCB. The proposed biaxial high-g accelerometer has potential applications in the aerospace, military, and transportation sectors.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Acceleration (104 m/s2) | 5 g | 8 g | 10 g | 13 g | 15 g | 18 g | 20 g |
Stress difference (MPa) | 20.1 | 32.2 | 40.4 | 52.6 | 60.4 | 72.5 | 80.7 |
Voltage (mV) | 69.4 | 111.2 | 139.5 | 181.6 | 208.5 | 250.3 | 278.6 |
Acceleration (104 m/s2) | 5 g | 8 g | 10 g | 13 g | 15 g | 18 g | 20 g |
Stress difference (MPa) | 20.6 | 32.7 | 41.2 | 53.6 | 61.4 | 74.0 | 82.1 |
Voltage (mV) | 71.1 | 112.9 | 142.2 | 185.1 | 212.0 | 255.5 | 283.5 |
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Wang, P.; Yang, Y.; Chen, M.; Zhang, C.; Wang, N.; Yang, F.; Peng, C.; Han, J.; Dai, Y. Design of a Biaxial High-G Piezoresistive Accelerometer with a Tension–Compression Structure. Micromachines 2023, 14, 1492. https://doi.org/10.3390/mi14081492
Wang P, Yang Y, Chen M, Zhang C, Wang N, Yang F, Peng C, Han J, Dai Y. Design of a Biaxial High-G Piezoresistive Accelerometer with a Tension–Compression Structure. Micromachines. 2023; 14(8):1492. https://doi.org/10.3390/mi14081492
Chicago/Turabian StyleWang, Peng, Yujun Yang, Manlong Chen, Changming Zhang, Nan Wang, Fan Yang, Chunlei Peng, Jike Han, and Yuqiang Dai. 2023. "Design of a Biaxial High-G Piezoresistive Accelerometer with a Tension–Compression Structure" Micromachines 14, no. 8: 1492. https://doi.org/10.3390/mi14081492
APA StyleWang, P., Yang, Y., Chen, M., Zhang, C., Wang, N., Yang, F., Peng, C., Han, J., & Dai, Y. (2023). Design of a Biaxial High-G Piezoresistive Accelerometer with a Tension–Compression Structure. Micromachines, 14(8), 1492. https://doi.org/10.3390/mi14081492