Hybrid Transverse Polar Navigation for High-Precision and Long-Term INSs

Transverse navigation has been proposed to help inertial navigation systems (INSs) fill the gap of polar navigation ability. However, as the transverse system does not have the ability of navigate globally, a complicated switch between the transverse and the traditional algorithms is necessary when...

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Veröffentlicht in:	Sensors (Basel, Switzerland) Switzerland), 2018-05, Vol.18 (5), p.1538
Hauptverfasser:	Wu, Ruonan, Wu, Qiuping, Han, Fengtian, Zhang, Rong, Hu, Peida, Li, Haixia
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Sprache:	eng
Schlagworte:	Accuracy Algorithms Computer simulation Damping Error analysis Exact solutions Horizontal orientation Inertial navigation Kinematics Mechanization Navigation systems Polar navigation Position errors Propagation Sensors
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creator	Wu, Ruonan Wu, Qiuping Han, Fengtian Zhang, Rong Hu, Peida Li, Haixia
description	Transverse navigation has been proposed to help inertial navigation systems (INSs) fill the gap of polar navigation ability. However, as the transverse system does not have the ability of navigate globally, a complicated switch between the transverse and the traditional algorithms is necessary when the system moves across the polar circles. To maintain the inner continuity and consistency of the core algorithm, a hybrid transverse polar navigation is proposed in this research based on a combination of Earth-fixed-frame mechanization and transverse-frame outputs. Furthermore, a thorough analysis of kinematic error characteristics, proper damping technology and corresponding long-term contributions of main error sources is conducted for the high-precision INSs. According to the analytical expressions of the long-term navigation errors in polar areas, the 24-h period symmetrical oscillation with a slowly divergent amplitude dominates the transverse horizontal position errors, and the first-order drift dominates the transverse azimuth error, which results from the gyro drift coefficients that occur in corresponding directions. Simulations are conducted to validate the theoretical analysis and the deduced analytical expressions. The results show that the proposed hybrid transverse navigation can ensure the same accuracy and oscillation characteristics in polar areas as the traditional algorithm in low and mid latitude regions.
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However, as the transverse system does not have the ability of navigate globally, a complicated switch between the transverse and the traditional algorithms is necessary when the system moves across the polar circles. To maintain the inner continuity and consistency of the core algorithm, a hybrid transverse polar navigation is proposed in this research based on a combination of Earth-fixed-frame mechanization and transverse-frame outputs. Furthermore, a thorough analysis of kinematic error characteristics, proper damping technology and corresponding long-term contributions of main error sources is conducted for the high-precision INSs. According to the analytical expressions of the long-term navigation errors in polar areas, the 24-h period symmetrical oscillation with a slowly divergent amplitude dominates the transverse horizontal position errors, and the first-order drift dominates the transverse azimuth error, which results from the gyro drift coefficients that occur in corresponding directions. Simulations are conducted to validate the theoretical analysis and the deduced analytical expressions. 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subjects	Accuracy Algorithms Computer simulation Damping Error analysis Exact solutions Horizontal orientation Inertial navigation Kinematics Mechanization Navigation systems Polar navigation Position errors Propagation Sensors
title	Hybrid Transverse Polar Navigation for High-Precision and Long-Term INSs
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