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Automatic acquisition algorithm for near-earth satellite target based on shape feature search

A near-Earth satellite, shape feature technology, applied in satellite radio beacon positioning systems, measurement devices, instruments, etc., can solve the problems of uncertainty of success, influence of measurement and control process, uncertainty of operation time, etc., to improve the success of automation efficiency, increase the search range, and shorten the capture time

Active Publication Date: 2017-05-31
CHINA XIAN SATELLITE CONTROL CENT
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Problems solved by technology

[0002] Most near-Earth satellites have the characteristics of strong mobility, low orbit height, and fast attenuation. In order to obtain more accurate orbit measurement data, ground monitoring and control stations often use large-aperture antennas, but the increase in antenna aperture means that the main lobe Narrowing of width, especially when large dynamic targets or when the orbit of the spacecraft out of control becomes unpredictable, the search and acquisition of the target becomes a difficult problem
At this time, the usual way to complete the target capture and tracking is to rely on the operator to manually scan and search the target, which relies more on the operator's experience accumulation, and the operation time is uncertain, and the success is uncertain, which greatly affects the normal measurement and control. The progress of the process

Method used

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  • Automatic acquisition algorithm for near-earth satellite target based on shape feature search
  • Automatic acquisition algorithm for near-earth satellite target based on shape feature search
  • Automatic acquisition algorithm for near-earth satellite target based on shape feature search

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Embodiment Construction

[0018] The present invention will be further described below in conjunction with the accompanying drawings and embodiments, and the present invention includes but not limited to the following embodiments.

[0019] Technical scheme of the present invention comprises the following steps:

[0020] Step 1: Collect antenna parameters

[0021] Select a measurement and control antenna A, its characteristic parameter is T={f, r}, f is the receiving frequency of the antenna, r is the radius of the antenna;

[0022] Step 2: Generate Antenna Pattern

[0023] Generate the pattern P of antenna A according to the characteristic parameter T={(a 1 ,e 1 | g 11 ),…,(a i ,e j | g ij ),…,(a m ,e n | g mn )}, where m is the number of points in the azimuth direction of the antenna pattern, n is the number of points in the elevation direction of the antenna pattern, a i is the coordinate of the antenna pattern in the azimuth direction, e j is the coordinate of the antenna pattern in the ...

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Abstract

The invention provides an automatic acquisition algorithm for a near-earth satellite target based on shape feature search. The automatic acquisition algorithm is characterized in that a directional diagram model of an antenna is built, then a change rate curve of voltage formed by relative movements of a target and the antenna is enabled to act as a curve to be detected, a starting point and an ending point which most conform features of the curve are searched in the directional diagram model of the antenna, and finally relative positions of the target and an electrical shaft of the antenna are determined by using the ending point, so that the antenna is controlled to complete acquisition and tracking for the target. It is proved by a practical verification result that the method can automatically complete acquisition and tracking for the target when the target moves in a sidelobe range, and manual scanning intervention is not required. Meanwhile, the method can also be applied to mainlobe and sidelobe discrimination. The method can effectively improves the search range of the antenna, shorten the acquisition time and improve the automatic success rate.

Description

technical field [0001] The invention belongs to the field of on-orbit spacecraft measurement and control management, and is suitable for intelligent search and capture of dynamic targets. Background technique [0002] Most near-Earth satellites have the characteristics of strong mobility, low orbit height, and fast attenuation. In order to obtain more accurate orbit measurement data, ground monitoring and control stations often use large-aperture antennas, but the increase in antenna aperture means that the main lobe The narrowing of the width, especially when the large dynamic target or when the orbit of the spacecraft loses control becomes unpredictable, the search and acquisition of the target becomes a difficult problem. At this time, the usual way to complete the target capture and tracking is to rely on the operator to manually scan and search the target, which relies more on the operator's experience accumulation, and the operation time is uncertain, and the success i...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G01S19/24
CPCG01S19/24
Inventor 李涵秋付枫钱建国全录贤张诚林令涛肖庆黄年全王引娣
Owner CHINA XIAN SATELLITE CONTROL CENT
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