High-Accuracy Modeling of Ship Deformation Based on Inertial Measuring Method

Er Kai Yuan; Gong Liu Yang

doi:10.4028/www.scientific.net/AMR.760-762.1227

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 760-762High-Accuracy Modeling of Ship Deformation Based...

High-Accuracy Modeling of Ship Deformation Based on Inertial Measuring Method

Abstract:

High-accuracy modeling is the key problem of ship deformation measurement based on inertial measuring method. This paper is to find a high-accuracy modeling method based on the ship deformation data measured by optical devices. According to different modeling methods, mathematical models are designed by the analysis of the initial measurement data. Wavelet analysis method is introduced in the process of modeling. Attitude matching method is selected as the simulation algorithm and Kalman filter equations are set up based on the algorithm. Simulation results show that the ship deformation can be represented accurately by mathematical models. The Precision Estimation result is better than 0.4''.

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Periodical:

Advanced Materials Research (Volumes 760-762)

Pages:

1227-1232

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.760-762.1227

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Online since:

September 2013

Authors:

Er Kai Yuan, Gong Liu Yang

Keywords:

High-Accuracy Modeling, Inertial Measuring Method, Kalman Filter (KF), Ship Deformation Measurement, Wavelet Analysis

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References

[1] A.V. Mochalov, A. Roumiantsev. Research of strapdown inertial navigation system on laser gyros in the attitude definition mode[C]. Proceedings of SPIE, (2002).

DOI: 10.1117/12.454658

Google Scholar

[2] Mochalov A.V. A system for measuring deformation of large-sized objects[C]/ RTO/ NATO. France, 1999, 15. 1–15. 9.

Google Scholar

[3] Mochalov A. V, Kazantsev．Use of the ring laser units for　measurement of the moving object deformation[C]. Proceedings of SPIE, 2002(4680): 85–92.

Google Scholar

[4] I.M. Okon, I.B. Visegant, D. E Lukjanov. Three-ayas Laser Gyroscopes Used in Measurement Tasks of Relative Angular Position of Shipbome Systems[C]. Proceedings of the SecondSoviet-Cinese Symposium, Lenmgra, 1991: 63~66.

Google Scholar

[5] J.X. Zheng, S.Q. Qin, X.S. Wang. Attitude matching method for ship deformation measurement[J]. Journal of Chinese InertialTechnology, 2010, 18(2): 175–180.

Google Scholar

[6] Alan M. Schnider. Kalman Filter Formulations for Transfer Alignment of Strapdown Inertial Units [J]. Navigation, 1983(30): 72~89.

DOI: 10.1002/j.2161-4296.1983.tb00824.x

Google Scholar

[7] Vaisgant I. B, Tupisev V. A, TyumenevaG.V. Sensitivity of Kalman filter in a task of definition of deformation of the ships deformation [J]. Gyroscopy and Navigation, 1993(2): 22~29.

Google Scholar

[8] J.X. Zheng, S.Q. Qin, X.S. Wang. Ship hull angular deformation measurement taking slow-varying quasi-static component into account[J]. Journal of Chinese InertialTechnology, 2010, 19(1): 6–10.

Google Scholar

[9] M. Wen, H.Y. Ji. Spectrum denoise by wavelet analyze and its realize in Matlab[J]. Modern Electronics Technique, 2003, 26(24): 47–49.

Google Scholar