CN101275847A - Ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft - Google Patents

Ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft Download PDF

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CN101275847A
CN101275847A CNA200710091005XA CN200710091005A CN101275847A CN 101275847 A CN101275847 A CN 101275847A CN A200710091005X A CNA200710091005X A CN A200710091005XA CN 200710091005 A CN200710091005 A CN 200710091005A CN 101275847 A CN101275847 A CN 101275847A
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sensor
earth
star
ultraviolet light
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郝云彩
王丽
蔡伟
应磊
刘梁栋
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Beijing Institute of Control Engineering
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Beijing Institute of Control Engineering
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Abstract

The invention provides a near infrared imaging autonomous navigation sensor system of a low orbit spacecraft, comprising an optical measurement imaging component, an infrared detector focal plane component, an inertial measurement unit, and an information processing and error correction processing unit component. Wherein, the optical measurement imaging component comprises an imaging lens, a star imaging replication reflector of star imaging and an earth imaging replication reflector. The invention mainly solves problems that the low orbit spacecraft doesn't depend on three axis attitude of a satellite navigation system and orbit altitude integrated high-precision real-time measurement. The invention adopts a near infrared lens or reflector system to image in large field and flat field, so as to overcome a shortcoming existed in existing technology ultraviolet sensor that a near infrared optical system is complex and has high cost. And the invention solves a problem of large dynamic range detection brought in by great difference of star and earth brightness via adopting a transmittance regional change filter. Adopting an integrated design of the optical measurement imaging component and the inertial measurement unit can reduce dimension weight and power consumption. The information processing and the error correction processing of multi-sensors can save resources and take advantage of information fusion.

Description

The ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft
Technical field
The present invention relates to a kind of technology that is applied to spacecraft independent navigation attitude and orbit measurement system, specifically relate to a kind of ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft.
Background technology
In spacecraft independent navigation field, there are multiple independent navigation attitude and positional information measuring system and method, disclose name as U.S. Honeywell Inc company in the European Patent Publication No EP0589387A1 of application on September 20th, 1993 and be called " Method and System for Determining 3 AxisSpacecraft Attitude ", i.e. " three spacecraft attitudes are determined method and system ".Adopt the ultraviolet detector earth edge UV radiation profile of 280nm~300nm spectral coverage, determine the pitching and the roll attitude information in the earth's core, utilize same detector to survey and determine yaw-position information perpendicular to the fixed star direction vector of optical axis direction.System adopts refluxing reflection mirror compression visual field, adopts two hemisphere to add the optical fiber image rotator big visual field curved surface image planes are carried out imaging.Adopt data processor that the earth and the fixed star image information that collect are handled, obtain 3 attitude informations.Though this scheme has solved the problems of measurement of three-axis attitude and orbit altitude.But the deficiency that exists is that the optical system material of employing ultraviolet spectral coverage is less, adopts semiglobe lens and fibre optic image transmission too complicated, the cost height; Fibre optic image transmission and image intensifier bring additional noise in conjunction with meeting, reduce precision.
U.S. NASA has announced a project in the works in its new flourishing age, be referred to as " inertia star gyro " (Inertial Stellar Compass), adopt star sensor and MEMS gyro composite design, utilize the nearly drift of proofreading and correct gyro in real time of high-precision attitude information of star sensor.The deficiency of this scheme is, star sensor is single, can provide higher precision on optical axis direction, but on perpendicular to the direction of optical axis nearly 1 magnitude of precise decreasing, therefore the MEMS gyro drift correction accuracy for this direction just is affected.
" system emulation journal " in March, 2005 Vol.17, No3, the article that P529 delivers " makes up big visual field star sensor starlight refraction autonomous navigation of satellite method and emulation thereof ", and described sensor adopts 3 common star sensor space intersection hexagonal angles to constitute combined system, observe 3 fixed stars at earth edge simultaneously, release accurate the earth's core vector according to the atmospheric refraction model.The weak point of this scheme is to have adopted 3 star sensors, and cost is higher, makes the optical axis intersection of 3 star sensors adjust the done with high accuracy difficulty.
U.S. Microcosm company has developed a kind of autonomous navigation system MANS (MicrocosmAutonomous Navigation System), comprising earth sensor, the Sun and the Moon sensor, star sensor, gyro and accelerometer, owing to be that multi-sensor is united definite three-axis attitude and position, so precision is very high.But system is too complicated, and has adopted the double cone earth sensor that has movable part, cost height.
Content of the present invention
The objective of the invention is to overcome the shortcoming of above-mentioned prior art, provide a kind of ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft, problems of measurement when it mainly solves low orbit spacecraft and does not rely on the integrated high-precision real of the three-axis attitude of satellite navigation system and orbit altitude.This sensor does not adopt packaged lens and image converter, and adopt big visual field flat field ultraviolet lens or reflective big visual field lens design and refluxing reflection mirror combination technique to overcome ultraviolet optics system complex and the high shortcoming of cost that U.S.'s ultraviolet sensors exists, eliminated in the past the autonomous navigation sensor deficiency of scheme separately, such as the cost height that brings by distributing multi-sensor and complicated optical system, it is inconsistent to combine three precision that design brings with the 3 axis MEMS gyro by single optical sensor, degenerate by the precision that image converter brings, by the multi-sensor distribution defectives such as the bulking value of bringing is big are installed.
The objective of the invention is to realize that by following technical proposals the ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft provided by the present invention comprises optical measurement image-forming assembly, ultraviolet light detector focal plane component, inertial measurement cluster, information processing and correction processing unit block; Wherein said optical measurement image-forming assembly comprises imaging lens, the refluxing reflection mirror of fixed star imaging and earth imaging refluxing reflection mirror.The photosurface of the detector of described detector focal plane component is installed on the imaging surface of optical measurement image-forming assembly, and the detector focal plane component will be fixed on the supporting construction of sensor system.Described MEMS inertial measurement cluster then comprises MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed, and each direction of principal axis of optical measurement coordinate system is parallel to the accelerometer that MEMS gyro that 3 quadratures install and 3 quadratures install (concrete mounting means referring to below in conjunction with the described content of Fig. 3) respectively.Described information processing and correction processing unit block 4 are to adopt message handler that each sensor information is handled, and the zero shift that then the star sensor metrical information is used for the MEMS gyro is proofreaied and correct.Export nearly real-time high-precision three-axis attitude information and orbit altitude information by the normal data communication interface at last.Star sensor ultraviolet spectral coverage of the present invention is selected wide as far as possible, and earth ultraviolet spectral coverage is elected 280nm~300nm as.
Star sensor in the ultraviolet light imaging type autonomous navigation sensor system of the low orbit spacecraft of integrated design and ultraviolet light quiescent imaging formula earth sensor are by adopting transmitance shared described optical imagery assembly of regional change optical filter and detector focal plane component, described transmitance regional change optical filter is installed near detector window, detector field of view is cut apart use, fringe region is that ultraviolet light quiescent imaging formula earth sensor uses, be used for to the imaging of earth atmosphere ultraviolet radiation band, the central area is that star sensor uses, and is used for to the fixed star imaging.Described star sensor is a kind of by fixed star imaging extraction and standard star picture library coupling being obtained its optical axis with respect to the pointing vector of inertial space; Described ultraviolet light quiescent imaging formula earth sensor is a kind of by earth center vector is extracted in earth imaging.Above-mentioned star sensor and ultraviolet light quiescent imaging formula earth sensor all have common image coordinates system, and its Z axle points to the ground direction of bowl along optical axis, and the row and column direction with detector array is consistent respectively with Y-axis for its X-axis.3 MEMS gyros all are the microelectromechanicpositioning gyros that adopts the MEMS technology to make, and they are installed in image coordinates respectively is on three parallel orthogonal axes directions of three axles.3 mems accelerometers all adopt the micro-electro-mechanical device of the measurement acceleration of motion of MEMS technology manufacturing, and weight is very light, and three installation shaft are that three direction of principal axis are consistent with the star sensor image coordinates.Above MEMS gyro and mems accelerometer all belong to the MEMS inertial measurement cluster, and their installation shaft is that three change in coordinate axis direction are consistent with star sensor and ultraviolet light quiescent imaging formula earth sensor image coordinates, is beneficial to same reference measurement.
That system after the integrated design has is in light weight, volume is little, low in energy consumption, characteristics such as precision is high, data updating rate is high, cost is low.
Below just relevant technology contents of the present invention and detailed description, existing conjunction with figs. and given embodiment describe as follows.
Description of drawings
The ultraviolet light imaging type autonomous navigation sensor structural representation of Fig. 1 low orbit spacecraft;
Fig. 2 is the ultraviolet light imaging type autonomous navigation sensor optical measurement segmentation scheme schematic diagram of low orbit spacecraft;
Fig. 3 is the concern synoptic diagram of optical measurement part image coordinates system with MEMS gyro and mems accelerometer measurement axis.
Embodiment
Referring to Fig. 1-Fig. 3, it Figure 1 shows that the ultraviolet light imaging type autonomous navigation sensor system structural representation of low orbit spacecraft, and the ultraviolet light imaging type autonomous navigation sensor system of described low orbit spacecraft comprises optical measurement image-forming assembly 1, detector focal plane component 2, inertial measurement cluster 3, information processing and correction processing unit block 4.5 is that earth ultraviolet is looked and seen the plane among Fig. 1, and 6 is fixed star, 7 earth edge imaging subsystems.
Described optical measurement image-forming assembly 1, it comprises imaging lens, the refluxing reflection mirror 23 of fixed star imaging and earth imaging refluxing reflection mirror 24,25, a plurality of sub-imaging systems that can distribute around optical axis 24 and 25 or the two one of make integrated polygonal pyramid part pattern, the remaining part of not making pyramid is made plane mirror, so that install and aim at, plate the desired reflectance coating of optical system at the part outer surface, 24,25 installation should be carried out in strict accordance with the designing requirement of imaging system, guarantees the visual field sensing.The photosurface of the detector of described detector focal plane component 2 is installed on the imaging surface of optical measurement image-forming assembly 1, and detector focal plane component 2 will be fixed on the supporting construction of sensor system.3 of described MEMS inertial measurement clusters comprise MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed, and each direction of principal axis of optical measurement coordinate system is parallel to the accelerometer that MEMS gyro that 3 quadratures install and 3 quadratures install (concrete mounting means referring to below in conjunction with the described content of Fig. 3) respectively.Described information processing and correction processing unit block 4 are to adopt message handler that each sensor information is handled, and the zero shift that then the star sensor metrical information is used for the MEMS gyro is proofreaied and correct.Export nearly real-time high-precision three-axis attitude information and orbit altitude information by the normal data communication interface at last.
The refluxing reflection mirror 23 of wherein said fixed star imaging and earth imaging refluxing reflection mirror 24,25, it mainly acts on is by refluxing reflection mirror measuring system to be divided into two passages, these two passages can quadrature, also can be non-orthogonal, decide according to user demand.Determine to make the transmissison characteristic of two passages the earth and fixed star to be imaged on simultaneously on the same detector, and have bigger dynamic range according to following invention formula (3) and invention formula (4).Detector is selected the photoelectric detector of response ultraviolet light spectral coverage, as adopting CCD (Charge Coupled Devices, charge-coupled image sensor), also can adopt APS (ActivePixel Sensor, CMOS active pixel sensor).
Referring to shown in Figure 1, the ultraviolet light imaging type autonomous navigation sensor scheme of described low orbit spacecraft comprises optical measurement part, inertia measurement part, information processing and three functional modules of correction.
For the optical measurement module, because earth subtended angle is bigger, generally greater than 120 °, thus adopt the single lens imaging will cause resolution to reduce, precise decreasing, and also excessive field angle can make visual field, edge illuminance of image plane fall excessive, causes not match.Therefore measure optical system for the autonomous navigation sensor of low-orbit satellite and will be designed to complex visual field, as can on the circumferencial direction of visual field, making up 6 to 8 subsystems by refluxing reflection mirror, each subsystem is respectively to a part of edge imaging of the earth, and the whole edge extracting of the earth will extract that conversion again is synthetic to be obtained by a plurality of subsystem imagings.The center field of view is the fixed star imaging region, and the edge field of view is an earth imaging region.
The compound schematic diagram of the single earth of low orbit sensor edge imaging subsystems and fixed star imaging passage is referring to accompanying drawing 2.7 is single sub-imaging system field range, as seen looks in earth ultraviolet and sees and covered earth edge and region on every side thereof on the planar radial direction, is evenly distributing several as 6 same sub-imaging systems in 360 ° of scopes of optical axis.Turn back by earth imaging refluxing reflection mirror 24 and 25 like this and can obtain the earth edge topography of respective numbers in the detector image planes, shown among Fig. 29.Optical imaging system is same, and two passages are cut apart by the visual field and realized that the angle of cut of two passages can be determined with request for utilization against changeing catoptron.Seeing through of imaging lens for ultraviolet spectrum.The luminance brightness balance of two passages realizes by dual mode: the one, and adjust the inlet of two passages and the optical transmittance between the refluxing reflection mirror and realize; The 2nd, realize by adding transmitance regional change optical filter near as the plane at detector, this optical filter has different transmitance in the central area with fringe region for same ultraviolet light spectral coverage, transmitance at center fixed star imaging border circular areas is big as far as possible, and the transmitance in annular visual field, earth imaging edge will be reduced to suitable scope.
If the ultraviolet spectral coverage of the response of detector is from λ 1To λ 2If the spectral transmittance of optical imagery camera lens part is P (λ), the detector spectral response rate is K (λ), earth imaging subsystems part transmitance except camera lens is Te (λ), the part transmitance of fixed star imaging passage except camera lens is Ts (λ), and the brightness range of the earth is Le from weak to strong before the incident sensor 1~Le 2, the brightness range of the most weak fixed star before the incident sensor of detection is Ls from weak to strong 1~Ls 2, the dynamic range of detector is D, the complex energy conversion coefficient of earth passage is Q 1, the complex energy conversion coefficient of fixed star passage is Q 2, then have:
∫ λ 1 λ 2 P ( λ ) K ( λ ) T e ( λ ) dλ = Q 1 - - - ( 1 )
∫ λ 1 λ 2 P ( λ ) K ( λ ) T s ( λ ) dλ = Q 2 - - - ( 2 )
Q 2 L e 2 Q 1 L s 1 ≤ D - - - ( 3 )
Q 2(L e2+L e1)≈Q 1(L s2+L s1)..................................................(4)
Select to determine Te and Ts, inequality (3) and approximate expression (4) are set up above making.
3 the MEMS gyro measurement axis installation requirement separately of quadrature is parallel with detector image-forming coordinate system three axle x, y, z respectively each other, the zero shift error that they produce is separately proofreaied and correct by the star sensor metrical information respectively, filtering method is adopted in bearing calibration, as the kalman filter method of expansion.Sensor will be exported the nearly angular speed and the attitude angle information in real time of 3 MEMS gyros, and error correction and information processing will be finished in information processing and correction processing unit.
3 the mounting means of the mems accelerometer of quadrature is identical with 3 MEMS gyros each other, also is that 3 measurement axis are parallel to imaging coordinate system three axle x, y, z respectively.3 accelerometers are the instantaneous acceleration of measurement of x, y, three axles of z respectively, and twice integration obtains the displacement parameter of the relative initial position of satellite thus.More than calculate and in information processing and correction processing unit, finish.
Information processing and correction processing unit block are the message handlers of sensor, the star chart coupling of responsible fixed star passage and the earth's core vector and the earth visual angle radius of earth passage extract, and the fixed star vector of also being responsible for the Star Sensor measurement is to the zero shift correction of MEMS gyro and the integral operation of accelerometer.
This scheme combines optics attitude and earth visual angle radius measurement and inertia attitude and acceleration analysis, has unified measuring basis, has reduced measuring system ground systematic error; Simultaneously the drift of MEMS gyro is shifted near real-time correction and improved measuring accuracy.Can obtain high-precision fixed star vector and the earth's core vector by star sensor and earth sensor, therefore can obtain high-precision three-axis attitude measurement result, utilize the earth sensor passage can measure the visual angle radius of the earth simultaneously, can calculate out the flight track height by earth image extraction and optical performance parameter test result again, but they are discrete values.Having proofreaied and correct zero shift adopt the 3 axis MEMS gyro can obtain very high attitude and change resolution, but there is bigger null value drift in it, as long as therefore just can obtain high-precision MEMS gyro attitude measurement result.Because the MEMS gyro is measured the parallel installation of image coordinates axle with star sensor with earth sensor, therefore have and the same measuring basis of star sensor, by the drift that the high precision inertial space attitude of star sensor measurement can be proofreaied and correct the MEMS gyro well, this is characteristics of this programme.
The restriction that is not subjected to the ultraviolet light spectral coverage is measured in navigation in the full shadow district, and earth atmosphere nightglow scattared energy is very strong, and earth sensor is worked on, and only the intense radiation layer height changes to some extent.Between sun is according to district and shadow region, exist ultraviolet intense radiation layer height to change, it is influential to extract precision to attitude, for reducing its influence, the less time interval of this section can adopt track extrapolation algorithm and the relative displacement of accelerometer measures satellite to change, and carries out the independent navigation based on star sensor, MEMS gyro, mems accelerometer.Related invention scheme solved high precision that static independent navigation measures, near in real time, problem such as low-cost, complete autonomous, round-the-clock, have the following advantages:
(1) Star Sensor and earth sensor adopt the ultraviolet light spectral coverage can take into account sun according to district and shadow region attitude measurement, have strengthened the sensor function;
(2) measurement target that adopts the optimized distribution method of inventing related beam-splitter spectrum transmitting section can take into account different brightness adopts same optical system and same detector image-forming.
(3) adopt star sensor, earth sensor, MEMS gyro, mems accelerometer to install and to reduce system errors for measurement, improve measuring accuracy with benchmark.
(4) adopt MEMS gyro, mems accelerometer can so that the earth atmosphere sun according to and near attitude and the positional accuracy measurement of shade having a common boundary be improved;
(5) adopt star sensor high-acruracy survey information to proofread and correct the zero shift of gyro at any time, can obtain nearly real-time high precision three-axis attitude information.
(6) adopt optics and the design of combined integratedization of inertia measurement can reduce dimensional weight and power consumption, multi-sensor information processing and correction processing can economize on resources, the advantage of performance information fusion.
Can finish full independent navigation measurement by round-the-clock, all can adopt star sensor, earth sensor, MEMS gyro and accelerometer to realize independently measuring entirely according to district and shadow region at sun.
Optical measurement image-forming assembly 1 is mainly for the earth and fixed star imaging, because low orbit is used, imaging has enough big field angle to the earth in requirement, adopts refluxing reflection mirror compression imaging viewing field, and the annular visual field that surpasses 110 °-150 ° is compressed in 30 ° to the 70 ° scopes.As shown in Figure 2, the responsive passage of fixed star is by the transfer center imaging region of imaging lens of the refluxing reflection mirror 23 of fixed star imaging, earth edge field range 7 is compressed in the imaging lens visual field by earth imaging refluxing reflection mirror 24,25, and is imaged onto in the external margin annular visual field of detector image planes 21.Can beyond earth imaging viewing field, expand an annular visual field again, make fixed star imaging in annular visual field, the size of earth passage visual field and fixed star passage visual field is determined mainly once to catch fixed star imaging quantity on detector to be no less than 3 probability be standard greater than 99% so that the whole day ball is any, requires earth edge picture to leave simultaneously outward and is not less than 5 ° leeway.Mainly extract come out the earth's core vector and calculate earth visual angle radius of marginal information and match for earth image.Mainly extract asterism center of energy coordinate for the star chart picture and carry out star chart coupling extraction fixed star vector.
Because earth subtended angle is bigger, different along with orbit altitude, as greater than 120 °, so adopt the single lens imaging will cause resolution to reduce, precise decreasing, and excessive field angle can make visual field, edge illuminance of image plane fall excessive, causes not match.Therefore measure optical system for the autonomous navigation sensor of low-orbit satellite and will be designed to complex visual field, promptly on the circumferencial direction of visual field, make up several as 6 to 8 subsystems by refluxing reflection mirror, each subsystem is respectively to a part of edge imaging of the earth, and the whole edge extracting of the earth will extract that conversion again is synthetic to be obtained by a plurality of subsystem imagings.The center field of view is the fixed star imaging region, and the edge field of view is an earth imaging region.
The compound schematic diagram of the single earth of low orbit sensor edge imaging subsystems and fixed star imaging passage is referring to Fig. 2.
Among the figure: 21 is imaging optical system; 22 is the detector image-forming face; 23 is fixed star imaging passage refluxing reflection mirror; 24 is one of sub-imaging system refluxing reflection mirror of earth imaging passage; 25 is two of the sub-imaging system refluxing reflection mirror of earth imaging passage; 6 is by the imaging fixed star; 7 is the sub-imaging system field range of earth imaging passage; 8 are earth view plane (observation station is looked the earth plane of seeing in orbit); 9 is earth image in the imaging surface; 10 is star chart picture in the imaging surface; 11 is the projection of boundary structure on imaging surface of each sub-imaging system.
Fig. 3 has represented the relation of optical measurement part image coordinates system with MEMS gyro and mems accelerometer measurement axis.
31 is the detector image-forming face, and its coordinate system xyz is as measuring basis,
The photosurface of detector is installed on the imaging surface of optical system, and is fixed on the supporting construction of sensor.
32 are Star Sensor and earth sensor optical system shared (being camera lens);
3 is the MEMS inertial measurement cluster, comprise MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed, each direction of principal axis of optical measurement coordinate system is parallel to MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed respectively, as shown in Figure 3,31 is the detector image-forming face among the figure, and x, y, z are respectively detector image coordinates axle; 32 is that Star Sensor and earth sensor are optical system shared; 33 is 3 MEMS gyros of quadrature each other; 34 is 3 mems accelerometers of quadrature each other.3 MEMS gyros are installed in respectively in the plane parallel with xy, xz, yz, measurement axis x separately 1, y 1, z 1Parallel with respective x, y, z axle respectively; 3 mems accelerometers are installed in respectively in the plane parallel with xy, xz, yz, measurement axis x separately 2, y 2, z 2Parallel with respective x, y, z axle respectively.The installation site of each inertia measurement sensor can be adjusted under this condition.
Among Fig. 1,4 are information processing and correction processing unit, adopt message handler that each sensor information is handled here, and the zero shift that then the star sensor metrical information is used for the MEMS gyro is proofreaied and correct.Export nearly real-time high-precision three-axis attitude information and orbit altitude information by the normal data communication interface at last.
In Fig. 1 and Fig. 2: 5 look for the UV radiation of catching object-earth of earth sensor and to see the plane.6 the object-fixed stars of catching for Star Sensor.7 is the field range of earth edge imaging subsystems.8 look for earth ultraviolet and to see the plane.
Referring again to Fig. 2 is the ultraviolet light imaging type autonomous navigation sensor scheme schematic diagram of low orbit spacecraft.21 is the imaging detector imaging surface among the figure, for the digital photoelectricity image device of ultraviolet response spectral coverage, as CCD (Charge Coupled Devices, charge-coupled image sensor) and ultraviolet APS (Active Pixel Sensor, CMOS active pixel sensor) etc.22 is Star Sensor and the shared optical system of earth sensor, adopts ultraviolet light design spectral coverage.
Constitute each functional module of foregoing invention, as quiescent imaging earth sensor, star sensor, MEMS gyro, mems accelerometer can based on information process unit individually or combination in any use, to satisfy different application targets.Can use separately as the star sensor assembly, also can unite use with quiescent imaging formula earth sensor, can also and quiescent imaging formula earth sensor, MEMS gyro, mems accelerometer thrin or two groups and use, the output corresponding information.Reduce when foregoing invention under the situation of assembly kind, the corresponding kind of non-common sparing of class component can take down.If when only needing the earth's core vector measurement, transmitance regional change optical filter and dependency structure thereof can remove, and the star sensor relevant portion in the image processing software can remove, and the MEMS assembly all can remove.Chang'e I lunar orbiter ultraviolet moon sensor and adopted ultraviolet moon imaging type earth sensor and scheme that star sensor is measured as three-axis attitude for another example, its star sensor is independent measurement assembly, ultraviolet moon sensor is another independent assembly, and ultraviolet moon sensor provides the moon heart vector of around-the-moon flight.Ultraviolet moon sensor has the method for setting up identical principle of work and month heart vector processing extraction with the described earth ultraviolet sensors of foregoing invention.
The described system of foregoing invention is except determining around the earth and lunar flight attitude and the position determines, and the attitude of being diversion and the independent navigation that can also be applied to other celestial body are measured.
Yet above-mentioned explanation only is embodiments of the invention, and is non-for limiting embodiments of the invention; All personages who is familiar with this skill, it complies with feature category of the present invention, other that done is equivalent to be changed or modification, selects or change of shape, the type of functional module and the increase and decrease of quantity etc. as size, material, all should be encompassed in following real the invention in institute's claim.

Claims (4)

1. the ultraviolet light imaging type autonomous navigation sensor system of a low orbit spacecraft is characterized in that it comprises optical measurement image-forming assembly, ultraviolet light detector focal plane component, inertial measurement cluster, information processing and correction processing unit block; Wherein said optical measurement image-forming assembly comprises imaging lens, the refluxing reflection mirror of fixed star imaging and earth imaging refluxing reflection mirror; The photosurface of the detector of described detector focal plane component is installed on the imaging surface of optical measurement image-forming assembly, and the detector focal plane component will be fixed on the supporting construction of sensor system.Described MEMS inertial measurement cluster then comprises MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed, and each direction of principal axis of optical measurement coordinate system is parallel to MEMS gyro and 3 accelerometers that quadrature is installed that 3 quadratures are installed respectively; Described information processing and correction processing unit block are to adopt message handler that each sensor information is handled, and it proofreaies and correct the zero shift that the star sensor metrical information is used for the MEMS gyro; Export nearly real-time high-precision three-axis attitude information and orbit altitude information by the normal data communication interface at last.
2. the ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft according to claim 1, it is characterized in that star sensor in the ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft and ultraviolet light quiescent imaging formula earth sensor are by adopting transmitance shared described optical imagery assembly of regional change optical filter and detector focal plane component, described transmitance regional change optical filter is installed near detector window, detector field of view is cut apart use, fringe region is that ultraviolet light quiescent imaging formula earth sensor uses, be used for to earth imaging, the central area is that star sensor uses, and is used for to the imaging of ultraviolet spectral coverage fixed star; Described star sensor is a kind of by fixed star imaging extraction and standard star picture library coupling being obtained its optical axis with respect to the pointing vector of inertial space; Described ultraviolet light quiescent imaging formula earth sensor is a kind of by earth center vector is extracted in earth imaging; Above-mentioned star sensor and ultraviolet light quiescent imaging formula earth sensor all have common image coordinates system, and its Z axle points to the ground direction of bowl along optical axis, and the row and column direction with detector array is consistent respectively with Y-axis for its X-axis.
3. the ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft according to claim 1 is characterized in that it is on three parallel orthogonal axes directions of three axles that 3 MEMS gyros described in the ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft are installed in image coordinates respectively; Three installation shaft of 3 mems accelerometers are that three direction of principal axis are consistent with the star sensor image coordinates; Described MEMS gyro is that three change in coordinate axis direction are consistent with their installation shaft of mems accelerometer with star sensor and ultraviolet light quiescent imaging formula earth sensor image coordinates.
4. the ultraviolet light imaging type autonomous navigation sensor system of high orbit spacecraft in according to claim 1, each functional module that it is characterized in that forming system is respectively star sensor, ultraviolet light quiescent imaging formula sensor, MEMS gyro, mems accelerometer, they can both based on information process unit separately or the combination in any collocation use.
CNA200710091005XA 2007-03-29 2007-03-29 Ultraviolet light imaging type autonomous navigation sensor system of low orbit spacecraft Pending CN101275847A (en)

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CN103604433B (en) * 2013-11-29 2016-01-20 北京航空航天大学 A kind of complex optics sensor and its implementation
CN105806346A (en) * 2014-12-31 2016-07-27 上海新跃仪表厂 Medium and high orbit constellation intersatellite photographic observation sensor and intersatellite angular distance measurement method
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