CIOMP OpenIR
Simulation and Optimization of Hemispherical Resonator’s Equivalent Bottom Angle for Frequency-Splitting Suppression
Z. Gao; S. Wang; Z. Wang and X. Ding
2023
发表期刊Micromachines
ISSN2072666X
卷号14期号:9
摘要As an inertial sensor with excellent performance, the hemispherical resonator gyro is widely used in aerospace, weapon navigation and other fields due to its advantages of high precision, high reliability, and long life. Due to the uneven distributions of material properties and mass of the resonator in the circumferential direction, the frequencies of the two 4-antinodes vibration modes (operational mode) of resonator in different directions are different, which is called frequency splitting. Frequency splitting is the main error source affecting the accuracy of the hemispherical resonator gyro and must be suppressed. The frequency splitting is related to the structure of the resonator. For the planar-electrode-type hemispherical resonator gyro, in order to suppress the frequency splitting from the structure, improve the accuracy of the hemispherical resonator gyro, and determine and optimize the equivalent bottom angle parameters of the hemispherical resonator, this paper starts from the thin shell theory, and the 4-antinodes vibration mode and waveform precession model of the hemispherical resonator are researched. The effect of the equivalent bottom angle on the 4-antinodes vibration mode frequency value under different boundary conditions is theoretically analyzed and simulated. The simulation results show that the equivalent bottom angle affects the 4-antinodes vibration mode of the hemispherical resonator through radial constraints. The hemispherical resonator with mid-surface radius  (Formula presented.)  and shell thickness  (Formula presented.)  is the optimization object, and the stem diameter D and fillet radius  (Formula presented.)  are experimental factors, with the 4-antinodes vibration mode frequency value and mass sensitivity factor as the response indexes. The central composite design is carried out to optimize the equivalent bottom angle parameters. The optimized structural parameters are: stem diameter  (Formula presented.), fillet radii  (Formula presented.),  (Formula presented.). The simulation results show that the 4-antinodes vibration mode frequency value is 5441.761 Hz, and the mass sensitivity factor is 3.91 Hz/mg, which meets the working and excitation requirements wonderfully. This research will provide guidance and reference for improving the accuracy of the hemispherical resonator gyro. © 2023 by the authors.
DOI10.3390/mi14091686
URL查看原文
收录类别sci ; ei
引用统计
文献类型期刊论文
条目标识符http://ir.ciomp.ac.cn/handle/181722/67481
专题中国科学院长春光学精密机械与物理研究所
推荐引用方式
GB/T 7714
Z. Gao,S. Wang,Z. Wang and X. Ding. Simulation and Optimization of Hemispherical Resonator’s Equivalent Bottom Angle for Frequency-Splitting Suppression[J]. Micromachines,2023,14(9).
APA Z. Gao,S. Wang,&Z. Wang and X. Ding.(2023).Simulation and Optimization of Hemispherical Resonator’s Equivalent Bottom Angle for Frequency-Splitting Suppression.Micromachines,14(9).
MLA Z. Gao,et al."Simulation and Optimization of Hemispherical Resonator’s Equivalent Bottom Angle for Frequency-Splitting Suppression".Micromachines 14.9(2023).
条目包含的文件 下载所有文件
文件名称/大小 文献类型 版本类型 开放类型 使用许可
Simulation and Optim(4871KB)期刊论文出版稿开放获取CC BY-NC-SA浏览 下载
个性服务
推荐该条目
保存到收藏夹
查看访问统计
导出为Endnote文件
谷歌学术
谷歌学术中相似的文章
[Z. Gao]的文章
[S. Wang]的文章
[Z. Wang and X. Ding]的文章
百度学术
百度学术中相似的文章
[Z. Gao]的文章
[S. Wang]的文章
[Z. Wang and X. Ding]的文章
必应学术
必应学术中相似的文章
[Z. Gao]的文章
[S. Wang]的文章
[Z. Wang and X. Ding]的文章
相关权益政策
暂无数据
收藏/分享
文件名: Simulation and Optimization of Hemispherical R.pdf
格式: Adobe PDF
所有评论 (0)
暂无评论
 

除非特别说明,本系统中所有内容都受版权保护,并保留所有权利。