A positioning method of shipborne satellite sensor based on the gravity characteristics of inertial system

Abstract

The invention discloses a shipborne star sensor positioning method based on inertial system gravity characteristics. A gravitational acceleration is extracted from specific force information outputted by an accelerometer through an adaptive filter, then high-precision horizontal attitude reference information is determined according to projection characteristics of the gravitational acceleration in the inertial system, and therefore star sensor high-precision positioning information is obtained. In the method, gravity information is extracted in a specific environment by utilization of the adaptive filter and inertial system gravity characteristics, a stable, independent and high-precision horizontal attitude reference is provided, and the shipborne star sensor positioning precision is raised.

Description

technical field [0001] The invention belongs to the field of navigation and positioning, in particular to a positioning method for a shipborne star sensor based on the gravity characteristics of an inertial system. Background technique [0002] As a widely used celestial body sensor, the star sensor can output the high-precision attitude of the installed carrier relative to the inertial space, and is currently the most accurate attitude-sensitive device. Due to the characteristics of fully autonomous navigation and high precision, this type of sensor is widely used in aerospace vehicles such as satellites, intercontinental strategic missiles, and spaceships. Also because of this feature, in recent years, star sensors have been gradually introduced into the navigation field and become a new type of marine navigation sensor. The basic principle of the marine star sensor is to introduce the horizontal attitude of the carrier on the basis of the attitude information of the iner...

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Problems solved by technology

In the article "New celestial assisted INS initial alignment method for lunarexplorer" published by Yang, ShuJie et al. in Volume 21, Issue 4, 2013 of "Journal of Chinese Inertial Technology", the impact of positioning error on platform error angle and altitude angle is analyzed. Due to the impact of measurement, a new INS / CNS deep integrated navigation algorithm based on astrometric height is proposed to overcome the limitation of the horizontal reference in CNS. difficulty of homework

In the Chinese invention patent "star sensor positioning method based on high-precision horizontal reference" with the notification number CN103604428A, the horizontal reference information required for star sensor positioning is obtained by combining the inertial navigation system with the star sensor, and the star sensor positioning is realized technology, but this invention will couple the horizontal attitude error accumulated by the inertial navigation over time to the position information of the star sensor, which will affect the navigation and positioning accuracy; "An INS / CNS Autonomous Navigation Scheme for Aerospace Vehicles", proposed a novel INS / CNS autonomous integrated navigation scheme based on starlight refraction technology. The nonlinear inertial navigation error propagation equation is used as the system state equation, which increases the difficulty of the filtering algorithm

The above literatures are all about the research on the positioning technology of star sensors, but the methods used are to use the INS to provide the horizontal attitude, which will inevitably introduce the divergent errors accumulated in the INS over time

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