SU1622759A1 - Apparatus for automatic decoding of space scanner suryvey data - Google Patents

Abstract

The invention relates to photogrammetry, in particular, to the damping of space imagery materials, and can be used in deciphering bispectral: images obtained as a result of space imaging 7 2 scanner imaging. The purpose of the invention is to increase the reliability of the decryption. The device consists of the first cylindrical lens 2 arranged in series along the optical axis of the laser 1, the spatial filter 3 located in the rear focal plane of the first cylindrical lynch 7. and formed in the form symmetrical with respect to the optical axis P1 parallel to the generator of the cylindrical surface of the lens 2 ,. a second cylindrical lens 4, the front focal plane of which is aligned with the rear focal plane of the first cylindrical lens 7 of the direct fourier transform; a topographic matched filter 8 made in the form of a photothermoplastic carrier and also arranged in series and optically coupled mirrors 9 optically coupled with a beam splitter 5, a lotosator 10 and a cylindrical lens 11 of the inverse Lurie transform, optically coupled to a holographic matched filter filter / 2 with S (L o to s) |

Description

rum 8, and a pair of photographic prints 12. In addition, the device consists of sequentially and electrically connected receivers 13, a control unit 14, electrically connected to a linear controlled transparency 6, a synchronization unit 15 and

control unit for topographic matched filter and photo shutter

J6, electrically connected with the holographic matched filter I and with the photo behind TV (t. 10, as well as the reading unit 17, electrically connected with

, line of lottoprimnikov 12. 1 Il.

The invention relates to photogrammetry, in particular, to the damping of 15 satellite imagery materials, and can be used in the interpretation of spectral images obtained from satellite imagery 20.

The aim of the invention is to increase the reliability of the decryption.

The drawing shows a schematic diagram of the device.

The device consists of a first cylindrical lens 2 arranged 25 in series along the optical axis of the laser 1, a spatial filter 3, a first cylindrical lens 30 located on the rear focal plane of the lens 2 and made in the form of a bank symmetrical with respect to the optical axis parallel to the cylindrical surface lenses 2 “of the second cylindrical lens 4, the front Focal — the plane of which is aligned with the rear focal plane of the first cylindrical lens 2, the beam splitter 5, the linear controlled trans 6, a cylindrical lens 7 pr - for the upcoming Lurie transformation, a holographic matched filter 8, made in the form of a photothermoplastic carrier (, g also arranged in series and optically connected 45 mirrors 9, optically connected to the beam splitter 5, and a cylindrical Lurie inverse transform lens 11, optically coupled to a holographic matched filter 8, and a ruler of 12 photo-detectors. In addition, the device includes sequentially and electrically connected receiver 13, a control unit 14, electrically connected to a linear controlled transponder 6, a synchronization unit 15, and a holographic control unit 16 and a matching photo filter 50.

55

15 20

25 30 - up to 45 50

55

rum electrically connected with a holographic matched filter 8 and a photoblock | 0, as well as a reading unit 17 electrically connected with a ruler of 12 photoreceivers,

The devices are working in the same way.

The video signal from the satellite enters the receiver 1} and as a sequence of scans (first scan the image of the object in the spectral range, then match the spectrum with another in the other range, then sdr.du1 MCH | (skp; n nepnov tgs; range-iortp, etc.) is an end-to-one, p1 unit of 14 instructions, which forms on a linear controlled drive a sequence in a form of a sequence of internal optical optical frames; ny. At the same time, in the feed on the transgarp 6, the image of the object is scanned in the first spectral range of the t5 synchronization with the help of the topographic coordinated filter control unit 16 and the viewfinder simultaneously; about,-; polygraphic matched {tiltra, made in the form of a photothermal carrier, cTifirouyiic rp-, personal status (recording mode) and 1GK1Ch 1th Lotto-receiver 10. f; result on the carrier 8 s helped ciddipichigo t 7 of the direct transformation, a logical specimen scan of the image of an object in the first spectral range is formed. ; 1p the luminous hologram of this spectrum of coherent radiation, forming the reference beam, is directed with the help of the light divider L to the mirror 9, which, in turn, sends the radiation through the open photocatalyst 10 to the carrier 8, at -ITOM pa the last one is a hologram, -) one-dimensional spatially about the image scan of an object in the first spectral range, which serves as a temporary эт reference. When the corresponding scan image is applied to the transparency 6 in the second spectral range, the synchronization unit 15 by means of the holographic-kmc control unit 16 controls the matched filter and photo camera and closes the Phototower 10 and transfers the carrier I to a light-insensitive state (correlation mode). At the same time, the spectrum of the scientifi chenigg of the object in the rtori spectral range is formed on the carrier 8 by means of a direct lens 7 direct transducer Lurie, where the correlation comparison with the corresponding spectrum of the image of the object in the first spectral range occurs. A cylindrical reverse conversion lurie lens 11 of Lurie in the lintel of 1 photodetector is a mutual correlation function of the image scans of an object in different cgral zones, information about the shape and size of which is read by the reader for further digital processing. Sotkp. Then the synchronization unit 15 by means of the control unit 16 is limited to the logical coordinated Lee. n, the horn with the photographic switch transfers the carrier R to the erase mode. After that the described CYCLE REPEAT TO TC I FOR SLGDy 0 CHP

lines (consisting of two corresponding image scans of an object in various specie ranges of the image of an object, etc.

Claims (1)

Claims of the Invention A device for automatic decoding of data of a space scapech survey, consisting of first and second lenses arranged in series along the optical axis of the laser, a linear controlled transparency. 0 direct lourier conversion lens, holographic matched filter, lourier round conversion lens, a line of photodetectors and an electrically connected receiver and control unit, as well as a readout unit electrically connected to the high impedance line p s with the rear focal plane of the second lens combined with the front focal plane of the second pikzy, the transparent transparency is electrically controlled with the control unit, and it means that it is 14 times more reliable; Uniform and optically coupled beam splitter, and Photo g, Mt., are interconnected bpsc splitter and control unit of the holographic ntp1 cmf of the Gogglesan filter and Photofedient, and the spatial nt filter is the light is the light pattern is the light is the light is the light pattern. lens and controllable transparency, photo shutter optically sgtzn with holographic matching n-HiiTi Filter made in the form of Photothermoplast light carrier, electrically controlled by a control unit (11 consistent matching (chy). ii Gg otoz Shutter, bgyuk gnnhro- 1Yzats1Y elg: TpiPi cicn associated with block vrT ir jH iinn, the control unit holographic rag1p i | cheskpm matched filter and Lotoeatvorom ° jiei Tpit4ecKH Lotozatvorom associated with, the first, second lens, and the lens forward and the reverse transform is made cylindrical, the cylindrical surfaces forming them are perpendicular to the control of the transparency; the transparent screen is located in the rear Focal plane of the first lens and is produced in a pid symmetrical with respect to the optical axis of the target, parallel to 5 th about RIL hl) tseG cylindrical surface perpog .tpnzy. five 0 five 0