Gravity Requirements for Compensation of Ultra-Precise Inertial Navigation

Jay Hyoun Kwon; Christopher Jekeli

doi:10.1017/S0373463305003395

Abstract

Precision inertial navigation depends not only on the quality of the inertial sensors (accelerometers and gyros), but also on the accuracy of the gravity compensation. With a view toward the next-generation inertial navigation systems, based on sensors whose errors contribute as little as a few metres per hour to the navigation error budget, we have analyzed the required quality of gravity compensation to the navigation solution. The investigation considered a standard compensation method using ground data to predict the gravity vector at altitude for aircraft free-inertial navigation. The navigation effects of the compensation errors were examined using gravity data in two gravimetrically distinct areas and a navigation simulator with parameters such as data noise and resolution, supplemental global gravity model noise, and on-track interpolation method. For a typical flight trajectory at 5 km altitude and 300 km/hr aircraft speed, the error in gravity compensation contributes less than 5 m to the position error after one hour of free-inertial navigation if the ground data are gridded with 2 arcmin resolution and are accurate to better than 5 mGal.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

JEKELI, CHRISTOPHER 2005. Navigation Error Analysis of Atom Interferometer Inertial Sensor. Navigation, Vol. 52, Issue. 1, p. 1.

Bongs, K. Launay, R. and Kasevich, M.A. 2006. High-order inertial phase shifts for time-domain atom interferometers. Applied Physics B, Vol. 84, Issue. 4, p. 599.

Jekeli, Christopher Lee, Jong-Ki and Kwon, Jay H. 2007. Modeling errors in upward continuation for INS gravity compensation. Journal of Geodesy, Vol. 81, Issue. 5, p. 297.

Richeson, Justin and Pines, Darryll 2007. GPS Denied Inertial Navigation Using Gravity Gradiometry.

Akeila, Ehad Salcic, Zoran and Swain, Akshya 2008. Direct gravity estimation and compensation in strapdown INS applications. p. 218.

Zatezalo, Aleksandar Vuletic, Vladan Baker, Paul and Poling, T. Craig 2008. Bose-Einstein interferometry and its applications to precision undersea navigation. p. 940.

Akeila, Ehad Salcic, Zoran and Swain, Akshya 2009. Recent Advances in Sensing Technology. Vol. 49, Issue. , p. 203.

Li, Zong-Tao Wu, Tie-Jun Lin, Can-Long and Ma, Long-Hua 2011. Field Programmable Gate Array Based Parallel Strapdown Algorithm Design for Strapdown Inertial Navigation Systems. Sensors, Vol. 11, Issue. 8, p. 7993.

Yoo, Young Min Lee, Sun Min Kwon, Jay Hyun Yu, Myeong Jong and Park, Chan Gook 2013. Profile-based TRN/INS Integration Algorithm Considering Terrain Roughness. Journal of Institute of Control, Robotics and Systems, Vol. 19, Issue. 2, p. 131.

Dai, Dongkai Wang, Xingshu Zhan, Dejun Huang, Zongsheng and Xiong, Hao 2014. An improved method for gravity disturbances compensation in INS/GPS integrated navigation. p. 148.

Jing, Wang Gongliu, Yang Xiangyun, Li and Jianhua, Cheng 2015. Research on time interval of gravity compensation for airborne INS. p. 5442.

Dai, Dongkai Wang, Xingshu Huang, Zongsheng and Zheng, Jiaxing 2015. Stochastic modeling the vertical deflection errors of EGM2008 for INS/GNSS integration. p. 5057.

Jung, Ae Young Choi, Kwang-Sun Lee, Young-Cheol and Lee, Jung Mo 2015. External Gravity Field in the Korean Peninsula Area. Economic and Environmental Geology, Vol. 48, Issue. 6, p. 451.

Wang, Jing Yang, Gongliu Li, Jing and Zhou, Xiao 2016. An Online Gravity Modeling Method Applied for High Precision Free-INS. Sensors, Vol. 16, Issue. 10, p. 1541.

Zhou, Xiao Yang, Gongliu Cai, Qingzhong and Wang, Jing 2016. A Novel Gravity Compensation Method for High Precision Free-INS Based on “Extreme Learning Machine”. Sensors, Vol. 16, Issue. 12, p. 2019.

Zhou, Xiao Yang, Gongliu Wang, Jing and Li, Jing 2016. An improved gravity compensation method for high-precision free-INS based on MEC–BP–AdaBoost. Measurement Science and Technology, Vol. 27, Issue. 12, p. 125007.

Wang, Jing Yang, Gongliu Li, Xiangyun and Zhou, Xiao 2016. Application of the spherical harmonic gravity model in high precision inertial navigation systems. Measurement Science and Technology, Vol. 27, Issue. 9, p. 095103.

Wu, Ruonan Wu, Qiuping Han, Fengtian Liu, Tianyi Hu, Peida and Li, Haixia 2016. Gravity Compensation Using EGM2008 for High-Precision Long-Term Inertial Navigation Systems. Sensors, Vol. 16, Issue. 12, p. 2177.

Tie, Junbo Wu, Meiping Cao, Juliang Lian, Junxiang and Cai, Shaokun 2017. The impact of initial alignment on compensation for deflection of vertical in inertial navigation. p. 381.

Wang, Jun Wang, Xingshu Yang, Shuai Zhu, Jing Nardell, Carl Xue, Suijian and Yang, Huaidong 2017. Gravity compensation in a Strapdown Inertial Navigation System to improve the attitude accuracy. p. 5.

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Gravity Requirements for Compensation of Ultra-Precise Inertial Navigation

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