Your search keyword '"Xiaoqi Liang"' showing total 6 results

1. The Influence of Ambient Temperature on the Sensitivity of MEMS Vector Hydrophone

Author

Peng Chen, Ting Lv, Shan Zhu, Wendong Zhang, Songxiang Ji, Xiaoqi Liang, Renxin Wang, Yifan Zhang, Guojun Zhang, and Chenge Li

Subjects

Microelectromechanical systems, Materials science, Hydrophone, Acoustics, Atmospheric temperature range, computer.software_genre, Simulation software, Environmental temperature, Operating temperature, Electrical and Electronic Engineering, Underwater, Instrumentation, Sensitivity (electronics), computer

Abstract

During underwater acoustic detection, the positioning accuracy of the bionic cilia MEMS vector hydrophone is affected by its own sensitivity. MEMS vector hydrophone operate in different temperature environments, so studies on the environmental temperature and the sensitivity of the MEMS vector hydrophone are of great significance. In this paper, based on the sensitivity of the MEMS vector hydrophone at room temperature (22°C), its sensitivity variation is studied within the temperature range of 0–40°C. The relationship between the temperature and the piezoresistor in the MEMS vector hydrophone is theoretically analyzed, and it is concluded that the sensitivity change is within ±0.6dB. The sensitivity change of MEMS vector hydrophone is proved to be within ±0.3 dB via COMSOL 5.4 simulation software, and the MEMS vector hydrophone is verified experimentally by the hydrophone temperature characteristic testing system. The results show that the variation of the sensitivity is within ±0.5 dB, which is basically consistent with the theoretical analysis results and simulation results. It can be said that under normal non-extreme ambient temperature, the operating temperature has little effect on the sensitivity of the MEMS vector hydrophone.

Published

2021

2. Research on the influence of hydrostatic pressure on the sensitivity of bionic cilia MEMS vector hydrophone

Author

Wendong Zhang, Songxiang Ji, Xiaoqi Liang, Guojun Zhang, Renxin Wang, Peng Chen, Shan Zhu, Yan Liu, Boyuan Jing, Yifan Zhang, and Chenge Li

Subjects

Applied Mathematics, Electrical and Electronic Engineering, Condensed Matter Physics, Instrumentation

Published

2022

3. Design of ciliated MEMS vector hydrophone based on stainless steel mesh cap

Author

Wendong Zhang, Xi Yang, Yanan Geng, Weirong Ren, Xiaoqi Liang, Songxiang Ji, Guojun Zhang, Renxin Wang, Peng Chen, Ting Lv, and Shan Zhu

Subjects

Microelectromechanical systems, Materials science, Hydrophone, Aperture, Applied Mathematics, Perforation (oil well), Bandwidth (computing), Electrical and Electronic Engineering, Low frequency, Composite material, Condensed Matter Physics, Instrumentation, Sensitivity (electronics)

Abstract

The polyurethane-encapsulated lateral line-inspired MEMS vector hydrophone has problems such as low-frequency sensitivity (10–80 Hz) loss and narrow working bandwidth. In order to eliminate these two problems, a new encapsulation with a stainless steel mesh cap structure was proposed. This paper first verified the sensitivity loss and narrow working bandwidth of the polyurethane encapsulation through experiments and simulations, analyzed the impact of the perforation rate, thickness, and aperture of the stainless steel mesh cap structure on the vector hydrophone through simulation, and finally made 8 types of stainless steel mesh cap with different apertures was tested experimentally. Finally, the experimental results show that the sensitivity of the stainless steel mesh encapsulation in the low frequency range (10–80 Hz) is improved by an average of 12 dB than that of the polyurethane encapsulation, and the working bandwidth has been increased from 10–210 Hz to 10–667 Hz.

Published

2022

4. Design and realization of sculpture-shaped ciliary MEMS vector hydrophone

Author

Xiaoyong Zhang, Songxiang Ji, Xi Yang, Guojun Zhang, Peng Chen, Ting Lv, Zhenzhen Shang, Wendong Zhang, Xiaoqi Liang, and Shan Zhu

Subjects

010302 applied physics, Physics, Microelectromechanical systems, Cantilever, Hydrophone, Frequency band, Acoustics, Metals and Alloys, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Directivity, Noise (electronics), Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Standing wave, 0103 physical sciences, Electrical and Electronic Engineering, 0210 nano-technology, Instrumentation, Sensitivity (electronics)

Abstract

The traditional design of cilium MEMS vector hydrophone (CVH) usually adds attachment to the cilium to increase the force-bearing area of the cilium, which improves the sensitivity of CVH but also greatly reduces the inherent frequency of hydrophone, and brings heavier burden to the cross-beam. Based on the radiation noise of ships that is generally below 1 kHz, this article designs a sculpture-shape cilium MEMS vector hydrophone (SCVH). Compared to traditional CVH, it enhances the sensitivity of hydrophone, increases the resolution of weak signal, and reaches the working frequency band of 1 kHz. In this paper, the stress analysis of cantilever beam is carried out, and then the appropriate size of SCVH is determined by simulation analysis. Finally, the sensitivity and directivity experiments in standing wave tube are carried out. The experimental results show that the sensitivity of SCVH at 1 kHz reaches -184.2 dB (0 dB = 1 V/μPa), 13.1 dB higher than traditional CVH. The working frequency band of SCVH is 20 Hz-1kHZ, and the depth of “8”-shaped directivity concave point is larger than 30 dB.

Published

2021

5. Design and realization of cap-shaped cilia MEMS vector hydrophone

Author

Shan Zhu, Guojun Zhang, Peng Chen, Wendong Zhang, Ting Lv, Xi Yang, Zhenzhen Shang, Xiaoyong Zhang, and Xiaoqi Liang

Subjects

Microelectromechanical systems, Physics, Cantilever, Hydrophone, Applied Mathematics, Acoustics, Bandwidth (signal processing), Condensed Matter Physics, Directivity, Electrical and Electronic Engineering, Underwater, Instrumentation, Realization (systems), Sensitivity (electronics)

Abstract

Ciliary MEMS vector hydrophone (CVH) has excellent performance in low-frequency detection, however, there is still the problem of poor sensitivity in some applications. A cap-shaped ciliary vector hydrophone (CCVH) is proposed in this paper. The microstructure not only ensures the working bandwidth of the hydrophone, but also increases the sensitivity. A single integration process is adopted to complete the pasting of the cap-shaped cilia and the cantilever beam, requiring no complicated secondary cilia integration process. Firstly, a mathematical model is established for theoretical derivation, and then the principle is verified via COMSOL simulation. Finally, test results show that the sensitivity of CCVH can reach −182.7 dB at 1 kHz (1 kHz, 0 dB@1 V/µPa). Compared with the CVH, the sensitivity has increased by 14.4 dB. Concave point depth of 8-shaped directivity is beyond 30 dB, which indicates that CCVH has an excellent ability to detect underwater ship noise.

Published

2021

6. Design and implementation of beaded cilia MEMS vector hydrophone

Author

Shan Zhu, Xi Yang, Shasha Yang, Zhenzhen Shang, Xiaoqi Liang, Wendong Zhang, Guojun Zhang, Peng Chen, Ting Lv, and Boyuan Jing

Subjects

Microelectromechanical systems, Physics, Hydrophone, Frequency band, Applied Mathematics, Acoustics, 020208 electrical & electronic engineering, 010401 analytical chemistry, 02 engineering and technology, Acoustic wave, Condensed Matter Physics, 01 natural sciences, Directivity, 0104 chemical sciences, 0202 electrical engineering, electronic engineering, information engineering, Calibration, Electrical and Electronic Engineering, Underwater, Instrumentation, Sensitivity (electronics)

Abstract

In view of the problem that the increased difficulty of underwater moving targets detection caused by the development of acoustic stealth technology, a beaded cilia MEMS vector hydrophone (BCVH) is proposed in this paper. Compared with previous cilia structures, it can enlarge the receiving area of acoustic wave to improve sensitivity without the introduction of additional structures. Meanwhile, the introduction of additional mass and the loss of working frequency band are reduced, and the structure is manufactured at one time. In this paper, the design scheme and optimal size of BCVH are determined via theoretical analysis and simulation, then vector hydrophone calibration system is used to verify it. The experimental results show that the sensitivity of BCVH reaches −183.3 dB (@1kHz, 0 d B = 1 V / μ P a ), 13.7 dB higher than bionic cilia MEMS vector hydrophone (CVH). Moreover, the depth of concave point of BCVH is more than 30 dB, which has a good directivity.

Published

2021