Design and Optimization of Hemispherical Resonators Based on PSO-BP and NSGA-II

Although one of the poster children of high-performance MEMS (Micro Electro Mechanical Systems) gyroscopes, the MEMS hemispherical resonator gyroscope (HRG) is faced with the barrier of technical and process limits, which makes it unable to form a resonator with the best structure. How to obtain the...

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Published in:Micromachines (Basel) 2023-05, Vol.14 (5), p.1054
Main Authors: Liu, Jinghao, Li, Pinghua, Zhuang, Xuye, Sheng, Yunlong, Qiao, Qi, Lv, Mingchen, Gao, Zhongfeng, Liao, Jialuo
Format: Article
Language:English
Subjects:
Back propagation networks
BP neural network
Deformation
Design optimization
Energy consumption
Finite element method
Gyroscopes
Heat
Heredity
Laser etching
Manufacturing
MEMS HRG
Microelectromechanical systems
NSGA-II
Parameters
Polysilicon
PSO
Resonators
Velocity
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container_issue 5
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container_title Micromachines (Basel)
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creator Liu, Jinghao
Li, Pinghua
Zhuang, Xuye
Sheng, Yunlong
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Gao, Zhongfeng
Liao, Jialuo
description Although one of the poster children of high-performance MEMS (Micro Electro Mechanical Systems) gyroscopes, the MEMS hemispherical resonator gyroscope (HRG) is faced with the barrier of technical and process limits, which makes it unable to form a resonator with the best structure. How to obtain the best resonator under specific technical and process limits is a significant topic for us. In this paper, the optimization of a MEMS polysilicon hemispherical resonator, designed by patterns based on PSO-BP and NSGA-II, was introduced. Firstly, the geometric parameters that significantly contribute to the performance of the resonator were determined via a thermoelastic model and process characteristics. Variety regulation between its performance parameters and geometric characteristics was discovered preliminarily using finite element simulation under a specified range. Then, the mapping between performance parameters and structure parameters was determined and stored in the BP neural network, which was optimized via PSO. Finally, the structure parameters in a specific numerical range corresponding to the best performance were obtained via the selection, heredity, and variation of NSGAII. Additionally, it was demonstrated using commercial finite element soft analysis that the output of the NSGAII, which corresponded to the Q factor of 42,454 and frequency difference of 8539, was a better structure for the resonator (generated by polysilicon under this process within a selected range) than the original. Instead of experimental processing, this study provides an effective and economical alternative for the design and optimization of high-performance HRGs under specific technical and process limits.
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subjects Back propagation networks
BP neural network
Deformation
Design optimization
Energy consumption
Finite element method
Gyroscopes
Heat
Heredity
Laser etching
Manufacturing
MEMS HRG
Microelectromechanical systems
NSGA-II
Parameters
Polysilicon
PSO
Resonators
Velocity
title Design and Optimization of Hemispherical Resonators Based on PSO-BP and NSGA-II
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