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Star sensor optical imaging system for deep space exploration spacecraft attitude-determination

An optical imaging system and star sensor technology, applied in the field of optical systems, can solve the problems of prolonged dynamic motion imaging integration time, inability to apply to the field of fixed attitude, slow attitude determination of satellites, etc., to reduce procurement difficulty, manufacturing cost, energy, etc. The effect of high concentration and improved positioning accuracy

Active Publication Date: 2016-04-06
CHANGCHUN INST OF OPTICS FINE MECHANICS & PHYSICS CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

This will lead to disadvantages such as low incident light energy received by the image detector per unit time, prolonged dynamic motion imaging integration time, slow image refresh rate, and slow speed of satellite attitude determination when observing targets such as faint small stars in deep space, which cannot be applied. In the field of attitude determination of spacecraft and satellites for deep space exploration in the future

Method used

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  • Star sensor optical imaging system for deep space exploration spacecraft attitude-determination
  • Star sensor optical imaging system for deep space exploration spacecraft attitude-determination
  • Star sensor optical imaging system for deep space exploration spacecraft attitude-determination

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Embodiment Construction

[0017] Such as figure 1 As shown, a star sensor optical imaging system for attitude determination of a deep-space exploration aircraft is coaxially arranged with a first reflector 1, a second reflector 2, a first positive meniscus lens 3, and a first negative curve The moon lens 4, the second negative meniscus lens 5, the second positive meniscus lens 6 and the detector 7, the incident light is reflected by the front surface 11 of the first reflector 1, and is incident on the rear surface 21 of the second reflector 2, and passes through it After reflection, it is incident on the first positive meniscus lens 3, and the incident light passes through the first positive meniscus lens 3, the first negative meniscus lens 4, the second negative meniscus lens 5 and the second positive meniscus lens 6, Finally received by detector 7.

[0018] The distance d1 between the front surface 11 of the first reflecting mirror 1 and the rear surface 21 of the second reflecting mirror 2 is 75mm<...

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Abstract

The invention discloses a star sensor optical imaging system for deep space exploration spacecraft attitude-determination, and belongs to the technical field of optical system. In order to overcome the problems existing in prior art, an incident light is reflected by a front surface of a first reflector, and is injected to a rear surface of a second reflector; then injected to a first positive meniscus lens after being reflected by the second reflector; the incident light passes through the first positive meniscus lens, a first negative meniscus lens, a second negative meniscus lens and a second positive meniscus lens in order, and then is received by a detector finally; a center distance between the front surface of the first reflector and the rear surface of the second reflector is d1; the center distance between the rear surface of the second reflector and the front surface of the first positive meniscus lens is d2; a center distance between the rear surface of the first positive meniscus lens and the front surface of the first negative meniscus lens is d3; a center distance between the rear surface of the first negative meniscus lens and the front surface of the second negative meniscus lens is d4; a center distance between the rear surface of the second negative meniscus lens and the front surface of the second positive meniscus lens is d5; and a center distance between the rear surface of the second positive meniscus lens and the detector is d6.

Description

technical field [0001] The invention relates to a star sensor optical imaging system for attitude determination of a deep space exploration aircraft, which can be applied to the attitude determination of an outer space deep space exploration aircraft and belongs to the technical field of optical systems. Background technique [0002] There are various imaging types of star sensors according to the range of wavelengths used and the types of detectors. The structure of the star sensor that has been reported so far mostly adopts the transmissive type of the fully transmissive lens, the focal length of the system is generally 20mm-60mm, and the effective entrance pupil diameter is generally 10mm-50mm. This will lead to disadvantages such as low incident light energy received by the image detector per unit time, prolonged dynamic motion imaging integration time, slow image refresh rate, and slow speed of satellite attitude determination when observing targets such as faint small ...

Claims

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Application Information

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IPC IPC(8): G02B17/08G01C21/02
CPCG01C21/02G02B17/082
Inventor 吕博刘伟奇姜珊冯睿
Owner CHANGCHUN INST OF OPTICS FINE MECHANICS & PHYSICS CHINESE ACAD OF SCI
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