SU1265686A1 - Electronic copying machine - Google Patents

Abstract

The invention relates to photography and can be used for piezoelement printing of motion-picture images and for printing aerial photographs, x-ray photographs with a decrease in scale. The purpose of the invention is to improve the quality of the image during microfilming and to expand the functionality of the device. The device contains an electron-beam (LU and SP O5 00 and

Description

tube 1. deflecting system iy 2, block 3 sweeps, beam-splitting system 4, optical forming systems 5 and 8, film channel 6 of negative 7, photodetector 12 and 15, .logifiers 13 and 16, analog subtractor 14, switches 17 and 22, analog switch 18, amplitude selector 19, processor 20, unit 21 for inputting a characteristic curve of positive 11, display 23, controller 24 for the magnitude of the feedback coefficient, controller 25, synchronizer 26; amplifier 27, converter 28, unit 29, Video signal level tie-ins, cardan suspension 30, electric drive 31, LED 32, amplifier 33. terminal sensors 34 and 35, focons 36 and 37, photodiodes 38 and 39, circuits OR 41 and 42, Introduction of new Elements and the formation of new connections between the elements of the device provide a unit-by-element mode with a decrease in the scale of the image with the possibility of performing a tone correction during printing. 2 Il.

The invention relates to photographs in particular to devices for printing single-image images with automatic exposure control and can be used for printing aerial photographs, x-ray photographs with a decrease in scale in the process of element-by-element printing with electronic masking,

The aim of the invention is to improve the image quality during microfiling and to expand the functionality of the device,

Fig, 1 shows the functional diagram of the proposed electronic copying device; in fig. 2 is a functional diagram of an optical system for scanning an instrument.

Electron-copying device. Supports cathode ray tube 1, deflecting cncTeNfy 2, block 3 sweeps, push the beam-splitting system 4, the first optical shaping system 5, the film channel 6 of the negative 7, the second optical forming system 8, the second beam-splitting system 9z film channel .10 positive 11, first photo-receiver 12, first logarithm 13, analog subtractor 14, second photodetector 15, second logarithm 16, first switch 17, analog switch 18, amplitude selector 19, processor 20, characteristic input block 21 of the positive 11 curve, the second switch 22, the display 23, the controller 24, the magnitude of the feedback coefficient, the controller 25, the magnitude of the exposure, the synchronous generator 26, the controlled feedback amplifier 27, the exponential converter 28, the video signal level binding unit 29, gimbal 30, two-axis electric drive 31, LED 32, impulse amplifier 33, end sensors 34 and 35, focons 36 and 37, photodiodes 38 and 39, carrier 40, first and second circuits OR 41 and 42.

Electronic copying device operates as follows.

Before starting work on an electronic copying device, the operator (not shown) calibrates the device according to the white level and the size of the printing raster. Calibration by raster size consists in specifying the geometrical dimensions of the printing raster, formed by the two-coordinate oscillation of the optical axis of the device relative to the center, located in the center of the gimbal 30, Swing in two diagonal dimensions of the raster is set using end sensors 34 and 35 - set in pairs along the perimeter Film channel 6 of the negative 7. The end sensors 34 and 35 consist of two pairs of foci 36 and 37 and photodiodes 38 and 39 installed in the center. Photodiodes 38 and 39 convert the light incident on the focons 36 and 37 into electrical signals, which through the first and second

OR circuits 41 and 42 arrive at inputs of processor 20. Focons 36 and 37 are installed with the ability to move negative 7 in the plane of the film channel 6 in order to set the desired raster size in a given section of negative 7. Relatively to sensors 34 and 35 installed optically an electronic copying system which is mounted on carrier 40.

The optical system consists of successively arranged cathode ray tube 1, the first beam-splitting system 4, the first optical forming system 5, the second optical forming system 8, the second beam-splitting system 9, the first photodetector 12, the second photodetector 15, an LED 32 which is mechanically connected with the gimbal 30. The latter is controlled by a two-coordinate electric drive 31, controlled by the processor 20 and syncro. low-frequency sync generator 26. Swing frequency (scanning) is set by processor 20, swing width is raster size, by end sensors 34 and 35. Raster is negative 7 and positive 11 in film planes

output channels 6 and 10 are formed by a combined sweep — a macro scan, performed by rocking the instrument’s optical system and a micro scan, formed by a microrasm using a cathode ray tube 1, i.e. macro scan scan spot. To ensure anisotropy of the sweep, the macrostrast is formed by the Lissajous figure, for which a voltage of close frequency is applied to a two-coordinate electric drive. The defocusing along the edges of the macroraust is insignificant, since the printing is carried out with a unsharp mask. Next, the device is installed first.

switch 17 in the Analysis mode. I

A negative is scanned with a 6-spot (microraster) constant luminance with a constant sweep rate of the optical system of the device relative to the gimbal. When scanning, a portion of the light flux through the first beam-splitting system 4 enters the input of the second photodetector 15. The irregularity of the glow of the macro- and microrasters is electrically transmitted through a logarithmic converter 16 to the first input of the analog subtractor 14. At the same time, another part of the light flux passing through the first optical forming system 5 and negative 6 and modulated by its transparencies, through the second optical shaping system 8 and the second beam-splitting system 9 is diverted to the input of the first second photodetector .12. An electrical signal proportional to the transparency of the negative 6, through a logarithmic converter 13, is fed to the second input of the analog subtractor 14. In the immediate vicinity of the optical input of the first photo receiver 12, an LED 32 is installed, which is connected to the output of the clock generator 26 via a controlled pulse generator 33 and turns on when the light reaches the focons 36 and 37, at these times the microrash of the cathode ray tube 1 is turned off. The output of the analog subtractor 14 through the second switch 22 is connected to the input of the display 23, on the screen of which an oscillogram of the optical density signal is displayed. The amplitude, the pulse frequency, is controlled via the controlled pulse amplifier 33. The operator sets the pulse amplitude equal to the amplitude of the signal from the field and with zero optical density, in this case, the density of the veil.

At the end of the calibration, in order to effectively determine the necessary parameters of the optimal image conversion in the case of element printing, the necessary masking coefficient and the required exposure value when obtaining a positive print with the specified gradation characteristics: a preliminary analysis of the gradation characteristics of the negative image is performed. For this, the film channel 6 is analyzed Negative 7. Switch operation mode 17 Printing analysis is set to Analysis. The cathode ray tube 1 and the scanning system are included. A negative is scanned with a 6-spot constant luminance with a constant swing speed of the instrument's optical system. When scanning, part of the luminous flux through the beam-splitting system 4 is retracted to the second (reference) photodetector 15, the electrical output of which is connected to the first input of the analog subtractor 14 via a logarithm 16 and the photodetector 15 is used to receive a signal of irregularity of the macroraster across the field, and . compensate for this unevenness.

Then, a portion of the light flux transmitted through negative 6 and modulated by its transparency, through the optical forming system 8 and the light-f5. The divider system 9 is led to the optical input of the first photodetector 12, which is proportional to the transparency of the negative 6 enters the logarithm 13, the output of which is connected to the second input of the analog subtractor 14. The logarithm 13 serves to convert the electrical transparency signal into signals of the optical density of the negative 6. From the output the analog An optical signal of optical density, taking into account the irregularity of the glow of the screen of the cathode-ray tube 1, is fed to the input of the analog key 18. The first input of the latter is connected to the output of the analog subtractor 14. The analog key 18 captures the amplitude values of the optical density of the negative 6 the time elements determined by the voltage pulses supplied to the second input of the analog switch 18 from the clock generator 26. The assignment of the analog switch 18 to limit the amount of incoming information and about the negative, i.e. perform a statistical sampling with a volume determined by the frequency of the control pulses of the voltage of the sync generator 26. From the output of the analog key 18, the amplitude modulated voltage pulses are fed to the amplitude selector 19, where the amplitude modulated optical density signals are measured in amplitude and in accordance with the magnitude of the amplitude The dyes are distributed over the P-channels of the sending device (not shown) of the processor 20, where the number of them is counted. Thus, a histogram of optical densities of the analyzed negative 6 is formed in the memory of the processor 20. Through the second switch 22, this histogram is output to the display screen 23. To the third input of the second switch, the output of the characteristic photo input curve block 21 of the positive photographic material, which is a digital densitometer, is connected exit The resulting characteristic curve is outputted through the second switch 22 to the display screen 23 and simultaneously arrives at the second input of the processor 20, where it is recorded in the memory of the device. The characteristic curve in the storage device of the processor 20 and on the screen of the display 23 takes its position in accordance with the sensitivity of positive photographic material. The op.operator observed on the display screen 23 the nature of the distribution of the optical densities of negative 6 and its position on the axis of optical densities, as well as the characteristic characteristic of the positive 11 curve and its position on the axis of the positive, by the regulator 24 of the magnitude of the feedback gain through functional A converter (not shown) of processor 20 modifies and models the histogram of optical densities of masked negative 6, and the regulator 25 of the exposure value through the functional converter of processor 20 sets the offset x Hectic curve along the axis of exposure. (The offset of the characteristic curve along the axis of exposure determines the scanning time (exposure) in the case of element-by-element printing of negative 6. Based on the obtained data on the distribution of optical densities of the masked negative bis, taking into account the characteristic curve, the functional converter of processor 20 performs the conversion of the optical densities of negative 6 into distribution optical densities on a future positive print, which is also displayed on the display 23. The histogram of optical densities on a positive print is determined by the position of the controllers 24 and 25, which unambiguously corresponds to the specified degree of masking, as well as to the appearance and shift of the characteristic curve of positive 11. Modeled in the processor 20, the distribution curve of optical densities of the future positive 11 gives the operator a priori information about the gradation characteristics of the print before it the actual values obtained. The values found for the values of the unmasking coefficient (gain of the feedback circuit) and the exposure are fixed in the processor 20, after ie that the processor translates the first switch 17 device operation mode is set to print. An elemental negative 6 is printed in positive 10, and the processor 20, in accordance with the simulated control parameters, controls the scanning cycle through the scanner block 3, the electron-beam tube 1 and the two-coordinate electric drive 31 with the cardan suspension 30, and the masking cycle through the controlled amplifier 27 zi, an potential transducer 28 and a block 29 for linking a video signal level to a cathode ray tube 1. For synchronous and bi-phase operation of an electronic copy device, a unit 3 sweeps, tax key 18, processor 20, controlled feedback amplifier 27, pulse amplifier 33, video signal level binding unit 29 and two, coordinate motor drive 31 are connected to a synchronous generator 26. In the process of element-by-element printing, zooming out by means of an optical pattern is tracked by processor 20 using end sensors, ZD and 35, installed in pairs and in parallel, and relative to each other - perpendicular, and containing focons 36 and 37 and photodiodes 38 and 39. The latter are connected by outputs to the corresponding inputs of the first the second and second circuits OR 41 and 42, which are connected to the inputs of the raster-sized processor 20, which controls the two-way gimbal 30 via the two-coordinate electric drive 31. The optical system of the device, which plays the role of an optical master, with which the optical forming systems are suspended 5 and 8 work only with central axial beams, and this is how the maximum possible resolution of the optical system of the device is achieved.

In comparison with the known device, it provides a unit-by-element mode with

zooming out the image with the possibility of performing a tone correction during printing.

Claims (1)

Invention Formula Electron-copying device containing a cathode-ray tube, the deflecting system of which is associated with the scanner unit, the first optical forming system, the first beam-splitting system ry, the film channel of the negative, the second optical forming system, the second beam-splitting system, located behind the cathode-ray tube positive film channel, while the negative film channel is optically coupled through the second optical forming system and the second beam-splitting system to the first photodetector, at the optical The first input has an LED connected via a pulse amplifier to the output of the synchronous generator, the output of the first photoreceiver is connected through the first logarifmator to the first input of the analog transmitter, and the screen of the cathode ray tube is optically connected to the second photoreceiver through the first optical forming system and the first beam-splitting system, the output which through the second logarithm is connected to the second input of the analog subtractor, the output of which is connected to the first input of the first switch, to the first input the second switch and the first input of an analog switch, the output of which is connected through an amplitude selector to the first input of the processor, containing the masking coefficient and exposure value controls, to the second input of the processor is connected the first output of the positive characteristic curve input block, the second output of which is through the second switch connected to the input of the display, the second output of the processor is connected to the second input of the second switch, the third output of the processor is connected to the second input of the first switch , the fourth processor output is connected to the first input of the controlled feedback amplifier, to the second input of which the output of the first switch is connected, and the output of the controlled feedback amplifier under