SU906027A1 - Scanning device of transmitting facsimile apparatus - Google Patents

Description

line and frame are optically coupled to the spatial filtering unit through the first beam splitting element, the optical element changing the beam polarization plane through the second beam splitting element connected to the first optical input of the first interference sensor and the first optical input of the second interfering sensor, first movable reflector is connected with the second optical input of the first interference sensor; the second movable reflector is connected with the second optical input of the second interference D91tchika.

Moreover, the first interference sensor contains a beam-splitting element, a conical reflector, as well as successively located first and second reflecting mirrors, a focusing lens, a polarizer and a photodetector, the beam-splitting element being optically on one side connected to the conical reflector, and on the other hand to the first reflect the mirror, while the side of the beam-splitting element facing the first reflecting mirror is the first and second optical inputs of the first interference sensor, and you the photodetector stroke is the output of the First Interference Sensor1a.

In addition, the second interference sensor contains a reflecting mirror, a first beam-splitting element, a conical reflector, a focusing lens and a second beam-splitting element arranged in series, as well as two polarizers and two photodetectors, the first beam-splitting element being optically connected to one side with a conical reflector, and on the other hand, with a reflecting mirror, the first optical input of the second interference sensor appears; the side of the first beam-splitting element, turning The second optical input of the second interference sensor and the output of the second beam-splitting element in the course of each of the two beams are installed in series with a polarizer and a photodetector, and the output of each of the two photodetectors is the corresponding output of the second interference sensor.

The drawing shows a structural electrical circuit of the proposed scanning device.

The deploying device of the transmitting photo-telegraph apparatus comprises successively located coherent radiation source 1, an optical feedback circuit 2, a spatial filtering unit 3,

block 4 scan by line and frame, clock generator 5, first beam splitting element b, optical element 7 changing the beam polarization plane, second beam splitting element 8, first interference sensor 9, second interference sensor 10, first movable reflector 11, second movable reflector 12 , the first and second blocks 13 and 14 of the formation of compensation signals, three reflecting mirrors 15-17, the first interference sensor 9 containing a beam-splitting element 18, which is optically coupled on one side with a conical the reflector 19, on the other hand, is optically parallel with the successive first and second reflecting mirrors 20 and 21, the focusing lens 22, the polarizer 23 and the photodetector 24, and the second interference sensor 10 contains the first beam-splitting element 25, which is on one side optically connected with a conical reflector 26, on the other hand with a focusing lens 27 sequentially located and a second beam-splitting element 28, which is optically connected in parallel with successively located first m polarizer 29 and the first photodetector 30, with the second polarizer 31 and the second photodetector 32, the scanning block 4 in line and frame consisting of a carriage 33, which is driven by the first actuator 34, the drum 35, rotated by the second actuator block 36,

Deploying the device works as follows.

The light beam, reflected from the mirror 17, is fed to the input of the block 4, which scans the original within the sweep element defined by the feed step of the carriage 33, Another part of the light beam, the first beam-splitting element 6 passes through the optical element 7 changing the field plane polarization that converts flat-polarized coherent radiation into circularly polarized radiation. From the output of the optical element 7, the light beam through the second beam-splitting element 8 enters the input of the first interference sensor 9 and through the mirror 15 to the input of the second interference sensor 10. Part of the light entering the input of the first integrating sensor 9. reflects the beam-splitting element 18 and falls on the first movable reflector 11 mounted on the carriage 33 of the block 4. Testing threefold reflection.

the light beam from the movable reflector 11 goes back to the beam-splitting element 18. At the same point of the beam-splitting element 18 comes a light beam that has experienced a twofold reflection from the conical reflector 19. When reflected from a metal beam-splitting surface, the beam polarizes backwards and changes since the rays undergo a different number of reflections, two beams with opposite directions of rotation of the polarization plane and the cutting plane arrive at the point of addition on the beam-splitting element 18. The losing position of the polarization plane depends on the path difference of these rays. Further, the resulting beam is reflected from mirrors 20 and 21 ,. is focused by the focusing lens 22, through the polarizer 23 on the photosensitive surface of the photodetector 24. The polarizer 23 converts the change in position of the polarization plane into the change in intensity of the light flux, which is perceived by the photodetector 24. By the pulse frequency at the output, you can judge the speed of movement of the carriage 33. The input of the photodetector 24 is connected to the input of the first block 13 for generating compensation signals. The second part of the light beam from the output of the second beam-splitting element 8, through the mirror 15, is directed to the first beam-splitting element 25 of the second interference sensor Y. Again, it is divided into two beams, which undergo a different number of reflections; the second movable reflector 12 is mounted on the axis of rotation of the block 4 {drum. 35), the fixed conical reflector 26 is folded at a certain point of the beam-splitting element 25 and collected by a focusing lens 27 which, through the second beam-splitting element 28, the first and second polarizers 29 and 31 collect light on the photosensitive surfaces of the first and second photodetectors 30 and 32. Paul Risers 29 and 31 are needed to turn the change in the position of the polarization plane into a change in the intensity of the light flux, the location of these polarizers relative to the beam-splitting surface at an angle of 45 effectiveness to obtain two electrical signals shifted by 90 ° and soderzhs1schih information not only about the amount of displacement, but also its direction. The signals from the outputs of the photodetectors 30 and 32 are fed to the corresponding inputs of the second block 14 to generate compensation signals. Thus, changing the drum position of the horizontal scanning unit and changing the carriage speed of the frame p-folding of the BJOTCH mortgages to the reference frequency of the first compensation signal generating unit 13, which stabilizes the speed of the carriage 33 moving to the frame scanning relative to this reference frequency. The operation of all nodes is synchronized by the sync generators 5.

Thus, the combination of a coherent light source, a mechanical sweep across the field of the original, an additional sweep inside the sweep element with interferometric meters allows 5 to achieve an increase in information productivity while increasing the information capacity and, thereby, to improve the qualitative and quantitative characteristics of the reproductive system.

Claims (3)

1. A scanning device of a transmitting photo-telegraph apparatus containing successively located coherent radiation source, an optical feedback unit and a spatial filtering unit, as well as a scanning unit for line and frame, the first, second and third inputs of which are connected to the corresponding outputs of the synchro-generator, 5 topics; that, in order to increase the accuracy of the video signal formation, the first beam-splitting element, the optical element for changing the plane of polarization of the beam and the second beam-splitting element, as well as the first interference sensor, the second interference sensor, the first movable reflector and the second movable reflector installed on 5, the scanning unit for the row and the frame, the first and second blocks of forming the compensation signals, wherein the output of the first interference sensor is connected to the first input of the first 0 of the compensation signal conditioning unit, the first and second outputs of the second interference sensor are connected to the corresponding inputs of the second signal conditioning unit 5, the third input of the synchronous generator connected to the fourth output, and the output connected to the second input of the first block of the formation of compensation signals, the output of which is connected to the fourth input of the scanning unit along the row and frame, and optically connected with the spatial filtering unit 5 through the first beam splitter Rg element I the optical element changing the plane of polarization of the beam through the second beam splitter element is connected with the first optical input of the first interference sensor and the first optical input of the second interference sensor; the first movable reflector is connected with the second optical input of the first interference sensor second movable reflector It is connected with the iMjiM optical input of the second interference sensor. 2. A device according to claim 1, characterized in that the first interference sensor comprises a beam-splitting element, a conical reflector, as well as sequentially arranged first and second reflecting mirrors, a focusing lens, a polarizer and a photodetector, and the beam-splitting element is optically connected on one side a conical reflector, and on the other hand with a first reflecting mirror, while the side of the beam-splitting element facing the first reflecting mirror is the first and second optical inputs of the first and the interference sensor, and the photon of the photodetector is the output of the first interference sensor. 3. The device according to claim L, characterized in that the second interference sensor comprises a reflective mirror, a first beam-splitting element, a conical reflector, a focusing lens arranged in series, and a second beam-splitting element, as well as two polarizers and two photodetectors, the first beam splitting the element on the one hand is optically coupled to the conical reflector, and on the other hand to the reflecting mirror, is the first optical input of the second interference sensor, while the side of the first 5 of the beam-splitting element facing the reflecting mirror is the second optical input of the second interference sensor, and at the output of the second beam-splitting element 0 elements in the course of each of the two beams are installed successively located polarizer and a photodetector. The output of each of the two photodetectors is the corresponding output of the second interference sensor. Sources of information taken into account in the examination 1. USSR author's certificate in application number 26393950 / 18-09, 06/13/78 (prototype).