Your search keyword '"frequency split"' showing total 15 results

1. Electrostatic compensation of structural imperfections in dynamically amplified dual-mass gyroscope

Author

Efimovskaya, Alexandra, Wang, Danmeng, Lin, Yu-Wei, and Shkel, Andrei M

Subjects

MEMS gyroscope, Dual-mass system, Precision electrostatic tuning, Fabrication imperfections, Anisoelasticity, Frequency split, Electrical and Electronic Engineering, Materials Engineering, Mechanical Engineering, Nanoscience & Nanotechnology

Abstract

This paper presents a study on dynamics of a dual-mass MEMS vibratory gyroscope in presence of fabrication imperfections and reports a method for precision electrostatic frequency tuning of the operational modes. A number of multi-mass MEMS gyroscopes have emerged in recent years pursuing different goals, such as dynamically balanced structure, increased bandwidth, and dynamic amplification. Along with many perceived advantages of multi-mass devices, several challenges associated with mode-matching in a system with increased number of degrees-of-freedom (DOF) have to be considered. This work shows that it is possible to apply the DC tuning techniques, similar to tuning a conventional single-mass gyroscope, to achieve the precision tuning in a dual-mass sensor, without losing advantages of increased DOF of the system. The presented frequency trimming technique is based on assessing the modes mismatch and cross-coupling between modes by means of fitting the experimental frequency response curves to the analytical solutions of the dual-mass system in presence of imperfections. The tuning algorithm involves two steps. First, the stiffness mismatch along the two axes and the anisoelasticity angles α and β are identified, then the tuning DC voltages for modification of diagonal, off-diagonal, and coupling terms in the stiffness matrix are chosen. The method of electrostatic tuning was validated through the experimental characterization of a dual-mass dynamically amplified gyroscope, where the coupling between the two operational modes was minimized and frequency split was reduced from 26 Hz down to 50 mHz, resulting in 17.5× increase in the gyroscope scale factor and significantly improved noise characteristics. The presented electrostatic compensation method is suitable for both off-line and on-line calibration.

Published

2018

2. Electrostatic compensation of structural imperfections in dynamically amplified dual-mass gyroscope

Author

Efimovskaya, A, Wang, D, Lin, YW, and Shkel, AM

Subjects

MEMS gyroscope, Dual-mass system, Precision electrostatic tuning, Fabrication imperfections, Anisoelasticity, Frequency split, Nanoscience & Nanotechnology, Electrical and Electronic Engineering, Materials Engineering, Mechanical Engineering

Abstract

This paper presents a study on dynamics of a dual-mass MEMS vibratory gyroscope in presence of fabrication imperfections and reports a method for precision electrostatic frequency tuning of the operational modes. A number of multi-mass MEMS gyroscopes have emerged in recent years pursuing different goals, such as dynamically balanced structure, increased bandwidth, and dynamic amplification. Along with many perceived advantages of multi-mass devices, several challenges associated with mode-matching in a system with increased number of degrees-of-freedom (DOF) have to be considered. This work shows that it is possible to apply the DC tuning techniques, similar to tuning a conventional single-mass gyroscope, to achieve the precision tuning in a dual-mass sensor, without losing advantages of increased DOF of the system. The presented frequency trimming technique is based on assessing the modes mismatch and cross-coupling between modes by means of fitting the experimental frequency response curves to the analytical solutions of the dual-mass system in presence of imperfections. The tuning algorithm involves two steps. First, the stiffness mismatch along the two axes and the anisoelasticity angles α and β are identified, then the tuning DC voltages for modification of diagonal, off-diagonal, and coupling terms in the stiffness matrix are chosen. The method of electrostatic tuning was validated through the experimental characterization of a dual-mass dynamically amplified gyroscope, where the coupling between the two operational modes was minimized and frequency split was reduced from 26 Hz down to 50 mHz, resulting in 17.5× increase in the gyroscope scale factor and significantly improved noise characteristics. The presented electrostatic compensation method is suitable for both off-line and on-line calibration.

Published

2018

3. Modeling and Analysis of a MEMS Vibrating Ring Gyroscope Subject to Imperfections

Author

Mehran Hosseini-Pishrobat, Erdinc Tatar, Hosseini-Pishrobat, Mehran, and Tatar, Erdinç

Subjects

Quadrature error, Mechanical Engineering, Vibrating ring, MEMS gyroscope, Imperfections, Electrical and Electronic Engineering, Frequency split

Abstract

We present a new mathematical model for a vibrating ring gyroscope (VRG) in the presence of imperfections, namely, structural defects and material anisotropy. As a novelty, we calculate the mode shapes of the internal suspension structure to enable a more accurate and modular analysis of the VRG’s mass and stiffness distributions. Solving the associated eigenvalue problem shows that imperfections result in the frequency split between the gyroscope’s operating mode shapes, rotating their orientation with respect to the nominal drive and sense axes. We then use perturbation analysis to solve the VRG’s equations of motion and analyze the quadrature error that arises from frequency/damping mismatch between the mode shapes. We use our model to detail the various effects of the etching-related undercuts, structural uncertainties, and Young’s modulus anisotropy–in the form of suitable space-dependent functions–on the mode shapes and the quadrature error for the first time. The results reveal that rings are robust against imperfection, while the straight beams used in the suspension system are most likely responsible for the frequency split and quadrature error. For example, 50 nm (0.5%) width variation in a beam that connects the VRG’s suspension to an anchored internal structure leads to 4700°/s quadrature error. To validate our modeling, using the experimental data from a fabricated 59 kHz VRG, we provide rigorous, comparative simulations against the finite element method (FEM).

Published

2022

4. A High-Precision Method of Stiffness Axes Identification for Axisymmetric Resonator Gyroscopes

Author

Junhao Xiong, Kaiyong Yang, Tao Xia, Jingyu Li, Yonglei Jia, Yunfeng Tao, Yao Pan, and Hui Luo

Subjects

Control and Systems Engineering, Mechanical Engineering, Coriolis vibratory gyroscopes, stiffness axes, frequency split, force-to-rebalance mode, Electrical and Electronic Engineering

Abstract

Axisymmetric resonators are key elements of Coriolis vibratory gyroscopes (CVGs). The performance of a CVG is closely related to the stiffness and damping symmetry of its resonator. The stiffness symmetry of a resonator can be effectively improved by electrostatic tuning or mechanical trimming, both of which need an accurate knowledge of the azimuth angles of the two stiffness axes of the resonator. Considering that the motion of a non-ideal axisymmetric resonator can be decomposed as two principal oscillations with two different natural frequencies along two orthogonal stiffness axes, this paper introduces a novel high-precision method of stiffness axes identification. The method is based on measurements of the phase difference between the signals detected at two orthogonal sensing electrodes when an axisymmetric resonator is released from all the control forces of the force-to-rebalance mode and from different initial pattern angles. Except for simplicity, our method works with the eight-electrodes configuration, in no need of additional electrodes or detectors. Furthermore, the method is insensitive to the variation of natural frequencies and operates properly in the cases of either large or small frequency splits. The introduced method is tested on a resonator gyroscope, and two stiffness axes azimuth angles are obtained with a resolution better than 0.1°. A comparison of the experimental results and theoretical model simulations confirmed the validity of our method.

Published

2022

5. Simulations and Experiments on the Vibrational Characteristics of Cylindrical Resonators with First Three Harmonic Errors

Author

Chen Liang, Kaiyong Yang, Yao Pan, Yunfeng Tao, Jingyu Li, Shilong Jin, and Hui Luo

Subjects

CRG, cylindrical resonator, first three harmonics, frequency split, Control and Systems Engineering, Mechanical Engineering, Electrical and Electronic Engineering

Abstract

A cylindrical resonator gyroscope is a kind of Coriolis gyroscope, which measures angular velocity or angle via processing of the standing wave. The symmetry of a cylindrical resonator is destroyed by different degrees of geometric nonuniformity and structural damage in the machining process. The uneven mass distribution caused by the asymmetry of the resonator can be expressed in the form of a Fourier series. The first three harmonics will reduce the anti-interference ability of the resonator to the external vibration, as well as increase the angular random walk and zero-bias drift of the gyroscope. In this paper, the frequency split of different modes caused by the first three harmonic errors and the displacement of the center of the cylindrical resonator bottom plate are obtained by simulation, and the relationship between them is explored. The experimental results on five fused silica cylindrical resonators are consistent with the simulation, confirming the linear relationship between the n = 1 frequency split and second harmonic error. A method for evaluating the first three harmonic errors of fused silica cylindrical resonators is provided.

Published

2022

6. A Novel Mechanical Frequency Tuning Method Based on Mass-Stiffness Decoupling for MEMS Gyroscopes

Author

Chuanfu Chen, Kai Wu, Kuo Lu, Qingsong Li, Chengxiang Wang, Xuezhong Wu, Beizhen Wang, and Dingbang Xiao

Subjects

ring MEMS gyroscopes, mass-stiffness decoupling, frequency split, femtosecond laser, frequency tuning, Control and Systems Engineering, Mechanical Engineering, Electrical and Electronic Engineering

Abstract

MEMS gyroscopes play an important role in inertial navigation measurements, which mainly works in n = 2 mode. However, mode matching is the basis for high-precision detection, which can improve the sensitivity, resolution, and signal-to-noise ratio of the gyroscopes. An initial frequency split is inevitably generated during the manufacturing process. There are two methods to eliminate the frequency split and to achieve mode matching for the gyroscopes, which are electrostatic tuning and mechanical trimming, respectively. In this paper, we report a novel ring MEMS resonator and a novel method of mechanical frequency tuning. The most prominent characteristic of the resonator is that 16 raised mass blocks are increased in the circumferential positions of the ring uniformly. This structural design can achieve mass-stiffness decoupling, which means that punching holes on the mass blocks only affects the mass distribution but the stiffness is almost unchanged for the resonator. We verify the mass-stiffness decoupling by way of comparing the simulation with the conventional resonator. In addition, we put up an online tuning platform based on a femtosecond laser and reduce a resonator’s frequency split from 23.3 Hz to 0.4 Hz, which reveals that the frequency split is linearly related to the removed mass. These findings will have a referential significance for other transducers.

Published

2022

7. A Novel Method for Estimating and Balancing the Second Harmonic Error of Cylindrical Fused Silica Resonators

Author

Hui Luo, Yao Pan, Kaiyong Yang, Yonglei Jia, Jianping Liu, and Yunfeng Tao

Subjects

frequency split, lcsh:Mechanical engineering and machinery, Acoustics, Angular velocity, 02 engineering and technology, 01 natural sciences, Article, law.invention, Resonator, law, cylindrical resonator, lcsh:TJ1-1570, Electrical and Electronic Engineering, Fourier series, Physics, Mechanical Engineering, 010401 analytical chemistry, second harmonic error, Gyroscope, 021001 nanoscience & nanotechnology, Symmetry (physics), 0104 chemical sciences, Vibration, chemical balancing, Control and Systems Engineering, Precession, Harmonic, 0210 nano-technology

Abstract

The cylindrical resonator gyroscope (CRG) is a type of Coriolis vibratory gyroscope which measures the angular velocity or angle through the precession of the elastic wave of the cylindrical resonator. The cylindrical fused silica resonator is an essential component of the CRG, the symmetry of which determines the bias drift and vibration stability of the gyroscope. The manufacturing errors breaking the symmetry of the resonator are usually described by Fourier series, and most studies are only focusing on analyzing and reducing the fourth harmonic error, the main error source of bias drift. The second harmonic error also is one of the obstacles for CRG towards high precision. Therefore, this paper provides a chemical method to evaluate and balance the second harmonic error of cylindrical fused silica resonators. The relation between the frequency split of the n = 1 mode and the second harmonic error of the resonator is obtained. Simulations are performed to analyze the effects of the first three harmonic errors on the frequency splits. The relation between the location of the low-frequency axis of n = 1 mode and the heavy axis of the second harmonic error is also analyzed by simulation. Chemical balancing experiments on two fused silica resonators demonstrate the feasibility of this balancing procedure, and show good consistency with theoretical and simulation analysis. The second harmonic error of the two resonators is reduced by 86.6% and 79.8%, respectively.

Published

2021

8. Effects of Structural Dimension Variation on the Vibration of MEMS Ring-Based Gyroscopes

Author

Xudong Zheng, Zhonghe Jin, Zhipeng Ma, Xiaoli Chen, Yiming Jin, and Xiaojun Jin

Subjects

frequency split, Microelectromechanical systems, Physics, Mechanical Engineering, Acoustics, Structural dimension, ring gyroscopes, Gyroscope, Ring (chemistry), Article, gyroscope modeling, law.invention, fabrication imperfection, Vibration, Control and Systems Engineering, law, geometrical compensation, TJ1-1570, Mechanical engineering and machinery, Electrical and Electronic Engineering, Variation (astronomy)

Abstract

This study investigated the effects of structural dimension variation arising from fabrication imperfections or active structural design on the vibration characteristics of a (100) single crystal silicon (SCS) ring-based Coriolis vibratory gyroscope. A mathematical model considering the geometrical irregularities and the anisotropy of Young’s modulus was developed via Lagrange’s equations for simulating the dynamical behavior of an imperfect ring-based gyroscope. The dynamical analyses are focused on the effects on the frequency split between two vibration modes of interest as well as the rotation of the principal axis of the 2θ mode pair, leading to modal coupling and the degradation of gyroscopic sensitivity. While both anisotropic Young’s modulus and nonideal deep trench verticality affect the frequency difference between two vibration modes, they have little contribution to deflecting the principal axis of the 2θ mode pair. However, the 4θ variations in the width of both the ring and the supporting beams cause modal coupling to occur and the degenerate 2θ mode pair to split in frequency. To aid the optimal design of MEMS ring-based gyroscopic sensors that has relatively high robustness to fabrication tolerance, a geometrical compensation based on the developed model is demonstrated to identify the geometries of the ring and the suspension.

Published

2021

9. Trimming of Imperfect Cylindrical Fused Silica Resonators by Chemical Etching

Author

Yonglei Jia, Yao Pan, Yunfeng Tao, Hui Luo, Jin Shilong, and Kaiyong Yang

Subjects

frequency split, Fabrication, Materials science, Acoustics, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, law.invention, Resonator, Quality (physics), law, cylindrical resonator, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, 010401 analytical chemistry, Gyroscope, 021001 nanoscience & nanotechnology, Isotropic etching, Atomic and Molecular Physics, and Optics, Symmetry (physics), chemical trimming, 0104 chemical sciences, Trimming, 0210 nano-technology, Material properties

Abstract

The cylindrical resonator gyroscope (CRG) is a kind of solid-state gyroscope with a wide application market. The cylindrical resonator is the key component of CRG, whose quality factor and symmetry will directly affect the performance of the gyroscope. Due to the material properties and fabrication limitations, the actual resonator always has some defects. Therefore, frequency trimming, i.e., altering the local mass or stiffness distribution by certain methods, is needed to improve the overall symmetry of the resonator. In this paper, we made further derivation based on the chemical trimming theory proposed by Basarab et al. We built up the relation between the frequency split and the balanced mass to determine the mass to be removed. Chemical trimming experiments were conducted on three cylindrical fused silica resonators. The frequency splits of the three resonators were around 0.05 Hz after chemical trimming. The relation between frequency split and balanced mass established from experimental data was consistent with the theoretical calculation. Therefore, frequency split can be reduced to lower than 0.05 Hz under rigorous theoretical calculation and optimized chemical trimming parameters.

Published

2019

10. Automatic Mode-Matching Method for MEMS Disk Resonator Gyroscopes Based on Virtual Coriolis Force

Author

Zhihu Ruan, Xukai Ding, Hongsheng Li, Jia Jia, and Zhengcheng Qin

Subjects

frequency split, Microelectromechanical systems, Physics, lcsh:Mechanical engineering and machinery, Mechanical Engineering, Acoustics, mode-matching, Gyroscope, Sense (electronics), electrostatic negative stiffness effect, Random walk, Signal, Article, law.invention, Resonator, Control and Systems Engineering, law, MEMS (Micro-electromechanical Systems) disk resonator gyroscope, Control system, lcsh:TJ1-1570, Electrical and Electronic Engineering, virtual Coriolis force, Voltage

Abstract

An automatic mode-matching method for MEMS (Micro-electromechanical Systems) disk resonator gyroscopes (DRGs) based on virtual Coriolis force is presented in this paper. For this mode-matching method, the additional tuning electrodes are not required to be designed, which simplifies the structure design. By using the quadratic relationship between the driving voltage and the electrostatic force, the virtual Coriolis force is obtained by applying an AC voltage whose frequency is half of the driving mode resonant frequency to the sense electrode. The phase difference between the virtual Coriolis force and the sense output signal is used for mode-matching. The structural characteristics and electrode distribution of the DRG are briefly introduced. Moreover, the mode-matching theories of the DRG are studied in detail. The scheme of the mode-matching control system is proposed. Simultaneously, the feasibility and effectiveness of the mode-matching method are verified by system simulation. The experimental results show that under the control of mode-matching at room temperature, the bias instability is reduced from 30.7575 ° /h to 2.8331 ° /h, and the Angle Random Walk (ARW) decreases from 1.0208 ° / h to 0.0524 ° / h . Compared with the mode mismatch condition, the ARW is improved by 19.48 times.

Published

2020

11. Automatic Frequency Tuning Technology for Dual-Mass MEMS Gyroscope Based on a Quadrature Modulation Signal

Author

Hongsheng Li, Xukai Ding, Jia Jia, and Yang Gao

Subjects

Quadrature modulation, frequency split, Acoustics, lcsh:Mechanical engineering and machinery, Musical tuning, 02 engineering and technology, Low frequency, 01 natural sciences, Article, law.invention, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, Microelectromechanical systems, Physics, frequency mismatch, Mechanical Engineering, 010401 analytical chemistry, Vibrating structure gyroscope, Bandwidth (signal processing), Gyroscope, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nonlinear system, Control and Systems Engineering, 0210 nano-technology, dual-mass MEMS gyroscope, frequency tuning, quadrature modulation signal

Abstract

In order to eliminate the frequency mismatch of MEMS (Microelectromechanical Systems) gyroscopes, this paper proposes a frequency tuning technology based on a quadrature modulation signal. A sinusoidal signal having a frequency greater the gyroscope operating bandwidth is applied to the quadrature stiffness correction combs, and the modulation signal containing the frequency split information is then excited at the gyroscope output. The effects of quadrature correction combs and frequency tuning combs on the resonant frequency of gyroscope are analyzed. The tuning principle based on low frequency input excitation is analyzed, and the tuning system adopting this principle is designed and simulated. The experiments are arranged to verify the theoretical analysis. The wide temperature range test (-20 ∘ C &ndash, 60 ∘ C ) demonstrates the reliability of the tuning system with a maximum mismatch frequency of less than 0.3 Hz. The scale factor test and static test were carried out at three temperature conditions (&minus, 20 ∘ C, room temperature, 60 ∘ C), and the scale factor, zero-bias instability, and angle random walk are improved. Moreover, the closed-loop detection method is adopted, which improves the scale factor nonlinearity and bandwidth under the premise of maintaining the same static performances compared with the open-loop detection by tuning.

Published

2018

12. Electrostatic compensation of structural imperfections in dynamically amplified dual-mass gyroscope

Author

Andrei M. Shkel, Alexandra Efimovskaya, Danmeng Wang, and Yu-Wei Lin

Subjects

Engineering, 02 engineering and technology, 01 natural sciences, Frequency split, Anisoelasticity, law.invention, Dual-mass system, law, Control theory, 0103 physical sciences, medicine, Electrical and Electronic Engineering, Nanoscience & Nanotechnology, Instrumentation, Stiffness matrix, 010302 applied physics, Microelectromechanical systems, Coupling, business.industry, Mechanical Engineering, Vibrating structure gyroscope, Metals and Alloys, Stiffness, Fabrication imperfections, Gyroscope, MEMS gyroscope, Precision electrostatic tuning, Materials Engineering, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Electrostatics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, medicine.symptom, 0210 nano-technology, business, Voltage

Abstract

This paper presents a study on dynamics of a dual-mass MEMS vibratory gyroscope in presence of fabrication imperfections and reports a method for precision electrostatic frequency tuning of the operational modes. A number of multi-mass MEMS gyroscopes have emerged in recent years pursuing different goals, such as dynamically balanced structure, increased bandwidth, and dynamic amplification. Along with many perceived advantages of multi-mass devices, several challenges associated with mode-matching in a system with increased number of degrees-of-freedom (DOF) have to be considered. This work shows that it is possible to apply the DC tuning techniques, similar to tuning a conventional single-mass gyroscope, to achieve the precision tuning in a dual-mass sensor, without losing advantages of increased DOF of the system. The presented frequency trimming technique is based on assessing the modes mismatch and cross-coupling between modes by means of fitting the experimental frequency response curves to the analytical solutions of the dual-mass system in presence of imperfections. The tuning algorithm involves two steps. First, the stiffness mismatch along the two axes and the anisoelasticity angles α and β are identified, then the tuning DC voltages for modification of diagonal, off-diagonal, and coupling terms in the stiffness matrix are chosen. The method of electrostatic tuning was validated through the experimental characterization of a dual-mass dynamically amplified gyroscope, where the coupling between the two operational modes was minimized and frequency split was reduced from 26 Hz down to 50 mHz, resulting in 17.5× increase in the gyroscope scale factor and significantly improved noise characteristics. The presented electrostatic compensation method is suitable for both off-line and on-line calibration.

Published

2018

13. Frequency Split Elimination Method for a Solid-State Vibratory Angular Rate Gyro with an Imperfect Axisymmetric-Shell Resonator

Author

Ning Liu, Hong Liu, Zhihong Deng, Mengyin Fu, and Lin Zhen

Subjects

frequency split, Engineering, Surface Properties, Rotational symmetry, Shell (structure), Rate gyro, vibratory gyro, lcsh:Chemical technology, Vibration, Biochemistry, Article, Analytical Chemistry, law.invention, Resonator, Circular motion, Optics, law, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, business.industry, Gyroscope, Acoustics, Mechanics, Models, Theoretical, Atomic and Molecular Physics, and Optics, Finite element method, vibration mode, axisymmetric shell, business

Abstract

The resonator of a solid-state vibratory gyro is responsible for sensing angular motion. Frequency splitting of an axisymmetric-shell resonator is a common problem caused by manufacturing defects. The defect causes a frequency difference between two working modes which consist of two nodes and two antinodes. The difference leads to the loss of gyroscopic effect, and thus the resonator cannot sense angular motion. In this paper, the resonator based on an axisymmetric multi-curved surface shell structure is investigated and an approach to eliminate frequency splits is proposed. Since axisymmetric multi-curved surface shell resonators are too complex to be modeled, this paper proposes a simplified model by focusing on a common property of the axisymmetric shell. The resonator with stochastic imperfections is made equivalent to a perfect shell with an imperfect mass point. Rayleigh's energy method is used in the theoretical analysis. Finite element modeling is used to demonstrate the effectiveness of the elimination approach. In real cases, a resonator's frequency split is eliminated by the proposed approach. In this paper, errors in the theoretical analysis are discussed and steps to be taken when the deviation between assumptions and the real situation is large are figured out. The resonator has good performance after processing. The elimination approach can be applied to any kind of solid-state vibratory gyro resonators with an axisymmetric shell structure.

Published

2015

14. Optical and Electrical Method Characterizing the Dynamic Behavior of the Fused Silica Cylindrical Resonator

Author

Tianliang Qu, Jie Yuan, Yonglei Jia, Kaiyong Yang, Zhinan Qiu, Yao Pan, Zhenfang Fan, and Hui Luo

Subjects

frequency split, Physics::General Physics, Materials science, Acoustics, Fast Fourier transform, 02 engineering and technology, lcsh:Chemical technology, Q factor, 01 natural sciences, Biochemistry, Article, Physics::Geophysics, capacitive detection, Analytical Chemistry, law.invention, Computer Science::Robotics, Physics::Popular Physics, Resonator, Quality (physics), Data acquisition, law, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, LabVIEW program, Signal processing, laser Doppler vibrometer, 010401 analytical chemistry, Gyroscope, Physics::Classical Physics, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, fused silica cylindrical resonant gyroscope, 0210 nano-technology, Laser Doppler vibrometer

Abstract

Fused silica cylindrical resonant gyroscope (CRG) is a novel high-precision solid-wave gyroscope, whose performance is primarily determined by the cylindrical resonator&rsquo, s frequency split and quality factor (Q factor). The laser Doppler vibrometer (LDV) is extensively used to measure the dynamic behavior of fused silica cylindrical resonators. An electrical method was proposed to characterize the dynamic behavior of the cylindrical resonator to enhance the measurement efficiency and decrease the equipment cost. With the data acquisition system and the designed signal analysis program based on LabVIEW software, the dynamic behavior of the fused silica cylindrical resonator can be analyzed automatically and quickly. We compared all the electrical measurement results with the optical detection by LDV, demonstrating that the fast Fourier transform (FFT) result of the resonant frequency measured by the electrical method was 0.12 Hz higher than that with the optical method. Thus, the frequency split measured by the electrical and optical methods was the same in 0.18 Hz, and the measurement of the Q factor was basically the same in 730,000. We conducted all measurements under the same operation condition, and the optical method was used as a reference, demonstrating that the electrical method could characterize the dynamic behavior of the fused silica cylindrical resonator and enhance the measurement efficiency.

Published

2019

15. Decreasing Frequency Splits of Hemispherical Resonators by Chemical Etching

Author

Yao Pan, Yonglei Jia, Kaiyong Yang, Tianliang Qu, Wang Yuting, and Hui Luo

Subjects

frequency split, Materials science, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, law.invention, Resonator, Quality (physics), Etching (microfabrication), law, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, hemispherical resonator, Hemispherical resonator gyroscope, Laser ablation, business.industry, 010401 analytical chemistry, Gyroscope, 021001 nanoscience & nanotechnology, Isotropic etching, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, chemical etching, Optoelectronics, Trimming, 0210 nano-technology, business

Abstract

The hemispherical resonator gyroscope (HRG) has attracted the interest of the world inertial navigation community because of its exceptional performance, ultra-high reliability and its potential to be miniaturized. These devices achieve their best performance when the differences in the frequencies of the two degenerate working modes are eliminated. Mechanical treatment, laser ablation, ion-beams etching, etc., have all been applied for the frequency tuning of resonators, however, they either require costly equipment and procedures, or alter the quality factors of the resonators significantly. In this paper, we experimentally investigated for the first time the use of a chemical etching procedure to decrease the frequency splits of hemispherical resonators. We provide a theoretical analysis of the chemical etching procedure, as well as the relation between frequency splits and mass errors. Then we demonstrate that the frequency split could be decreased to below 0.05 Hz by the proposed chemical etching procedure. Results also showed that the chemical etching method caused no damage to the quality factors. Compared with other tuning methods, the chemical etching method is convenient to implement, requiring less time and labor input. It can be regarded as an effective trimming method for obtaining medium accuracy hemispherical resonator gyroscopes.

Published

2018