SU1059535A1 - Electronic copying instrument - Google Patents

Abstract

ELECTRONIC-COPY DEVICE containing a cathode-ray tube, the diverting system of which is connected to the scanner unit, the optical forming system, a node for placing negative and positive, a photodetector, the output of which is electrically connected through a logarithmizer and a switch of the type of work analyzing the print with the first input of the controlled amplifier feedback, a connected output to the input of an exponential converter, an analog switch connected through an amplitude selector to the first input of the processor, the first output to The second output of the processor is connected to the first input of the switch, the output of which is connected to the display, and the second input of the switch is connected to the first output of the input block of the positive characteristic curve, the second output of which is connected to the second input of the processor, - and the third processor input is connected to the output of the synchro generator, to which the analog key input is connected, to the third and fourth processor outputs are connected the controls for the exposure value and the gain value Feedback circuits, characterized in that, in order to reduce the anisotropy of the frequency-contrast correction and enable control of the distribution of the light intensity in the scanning spot, additional optical forming system, deflection system and sweep generator, the first synchronous motor, are first introduced system of automatic regulation, first feedback photosensor, second synchronous electric motor, second automatic regulation system, second photosensor connection, the actuator of the main forming system, microscopic scanning path generator, additional switch, integrator, video signal level white level block, luminance video amplifier, aperture signal video amplifier, additional exponential converter, aperture regulator of scanning microscope, SP teletype , a movable carriage with a spindle screw, with a scanner unit; connected to the output of a scanning microplate trajectory generator, the first Ob input of which is connected to the processor's fifth output, and the second input to the output of the synchro-generator, while the electron-beam tube is optically connected to the photoreceiver via successively located main optical forming system connected with an actuator connected to the sixth output of the processor; a node for accommodating the negative and positive, made transparent and mounted for movement, and an additional element cally forming system, the cathode ray tube, the base

Description

and the additional optical forming systems and the photodetector are located coaxially and perpendicular to the surface of the node to accommodate the negative and positive connected through the first synchronous motor to the output of the first automatic control system, to the first input of which is connected: the output of the first feedback photosensor, and to the second the sync generator output is connected to the input, the electron-beam tube, the main and additional deflection systems, the scanner unit, the main optical forming system with an actuator, an additional optical shaping system and a photodetector are mounted on a movable carriage associated with a lead screw connected to the shaft of the second synchronous electric motor connected. The output of the second automatic control system, to the first input of which is connected the output of the second feedback photosensor mounted on the shaft of the lead screw, and the second input also contains the output of the synchro generator, the outputs of the first and second reverse photosensors and the output of the synchronous generator are also connected

to the inputs of the additional sweep generator, the output of which is connected to the additional deflection system, while the output of the logarithmizer is connected directly to the first input of the additional switch,

; the seventh processor output is connected to the second input through the integrator, the seventh output of the additional switch, the output of the additional switch 1 is connected to the input of the analog switch, the output of the exponential converter via cable: the amplifier of the luminance signal, to the second input of which the first output of the video signal linker is connected by

. the white level is connected to the modulating electrode of the cathode-ray tube, to the focusing electrode of which the output of the video amplifier of the aperture signal is connected, the first input of which is connected to the eighth output of the processor through the additional exponential converter and the second input of the video signal level block connected to the output of the synchro-generator; the aperture controller of the scanning microplate is connected to the fourth input of the processor.

The invention relates to photography, cinematography, printing, in particular, to devices for printing photo images with automatic masking and automatic exposure control.  Known electron-copying device A device containing a scanning light source - a cathode-ray tube, a deflecting system of which is connected to a scanner unit, an optical projection system sequentially located behind the cathode-ray tube, a negative and positive photomultiplier tube electrically coupled to a Electron beam tube through a controlled reverse feedback amplifier vj.  The disadvantage of such a device is the need for the operator to make several test prints at different values of the masking coefficient and different values of the exposure value to obtain a photo print with the desired gradation characteristics.  The number of samples depends on the experience of the operator, and the accuracy of determining the values of the masking coefficient and the exposure is determined on the basis of a subjective assessment of the obtained image on the best (subjective) print.  The closest technical solution to the present invention is an electron-copying device containing a cathode-ray tube, the deflecting system of which is connected to a scanner unit, a negative, optically connected with a positive and photodetector, the output of which is electrically connected through a logarithm and type of work switch. the first EMLM input of a controlled feedback amplifier, connected by an output to the input of an exponential converter, an Angshog switch connected via an amplitude selector to the first the processor input, the first output of which is connected to the second input of the feedback amplifier, and the second output of the processor to the first input of the switch, the output of which is connected to the display, the second input to the first output of the positive characteristic curve input block, the second output of which is connected to the second the processor input, and the third processor input is connected to the output of the synchronous generator, to which the analog key input is connected, the scanner unit, and to the third and fourth processor outputs, the exposure value controls are connected and gain feedback loop h.  The main drawback of the device is that the channel uses only a single image element video signal in the analysis, which limits the quality of interpreting black-and-white or color-separated images obtained on the printout.  The drawback of the device is the use of anisotropic sweep, which causes distortions in the scanning direction due to the video signal delay in the feedback circuit, and there is no control over the distribution of intensity in the scanning spot, which sharply limits the quality of the frequency-contrast correction to be printed to a positive images.  The purpose of the invention is to reduce the anisotropy of the frequency-contrast correction and to ensure the possibility of controlling the distribution of the light intensity in the scanning spot.  This goal is achieved in that an electron-copying device containing a cathode-ray tube, the deflecting system of which is connected to the scanner unit, an optical forming system, a node for accommodating negative and positive, a photodetector, the output of which is electrically connected through a logarithmizer and a type of work print analysis with the first input of the controlled feedback amplifier, the connected output to the input of the exponential converter, the analog switch connected through the amplitude selector to the first the processor input, the first output of which is connected to the second input of the feedback amplifier, and the second output of the processor to the first input of the colmmatr, whose output is connected to the display, and the second input of which is connected to the first output of the input block of the characteristic positive curve, the second output of which is connected to the second input of the processor and the third input of the processor is connected to the output of the synchronous generator, to which the input of the analog switch is connected, and to the third and fourth outputs of the processor, the controls for the exposure value and the coefficient value are connected booster communication circuit amplification, additional optical forming system, deflection system and sweep generator, perfcdl synchronous motor, new automatic control system, first feedback sensor, second synchronous motor, second feedback sensor, zi, actuator of the main forming system, generator of the scanning micropath trajectory, additional switch, integrator, video signal anchor block white, video signal amplifier, aperture signal video amplifier, additional exponential converter, microtransmitter aperture controller, teletype, movable carriage with lead screw, the scanner unit connected to the scanning microplot trajectory, the first input of which is connected to n processor output, and the second input to the output of the synchro-generator, while the electron beam tube is optically connected to the photodetector via successively located main optical forming system associated with the executive. the mechanism connected to the sixth output of the processor, the node for placing the negative and positive, made transparent and mounted for movement, and an additional optical forming system, while the electron beam tube, the main and r additional optical forming systems and the photodetector are coaxially and perpendicular to the surface of the node for placing the negative and positive, connected through the first synchronous motor to the output of the first automatic control system, to the first in the output of which is connected to the output of the first photosensor feedback, and the output of the synchro-generator is connected to the second input, the electron-beam tube, the main and additional deflecting systems, the scanner unit, the main optical forming system with the actuator / additional optical forming system and the photodetector are mounted on the moving carriage associated with the lead screw connected to the second synchronous shaft.  an electric motor connected to the output of the second automatic control system, the first input of which is connected to the output of the second feedback photo sensor mounted on the spindle shaft, and to the second input is the output of a synchronous generator; the outputs of the first and second feedback photosensors and the output of the synchronous generator are also connected to the inputs of the additional sweep generator, the output of which is connected) to the additional deflection system, while the output of the logarithmizer is connected directly to the first input of the additional switch, and to its second input through the integrator, to the seventh output of the processor is connected to the third input of the additional switch, the output of the additional switch is connected to the input of the analog switch, the output of the exponential conversion through the luminance video amplifier, to the second input of which the first output of the video signal block is connected, the cell is connected to the modulating electrode of the cathode-ray tube, to the focusing electrode of which the output of the video amplifier of the aperture is connected, the first input of which is connected to the eighth through an additional exponential converter the output of the processor, e, the second input - to the second output of the block of the video signal by the white level, the input of which is connected to the output of the sync generator to h tvertomu input processor connected to the controller microspots scanning aperture.  FIG. 1 shows a functional diagram of an electronic copying device; in fig. 2 - view of macro and micro scan; in fig. H - view of functions on the display screen; in fig. 4 - the course of I optical rays in the optical system of the device.  The electron-copying device contains a cathode-ray tube 1 deflecting system 2, a block of 3 scrolls, an additional deflecting system 4, an additional sweep generator 5, a lens b, an executive mechanism 7 of lens 6, a negative 8, a positive 9, a mobile node 10 for fixing the negative 8 and the positive 9 additional optical forming system 11, the photodetector 12, the first synchronous electric motor 13, the first automatic control system 14, the first feedback photosensor 15, the movable carriage 16, the driving screw 17, synchronous motor 18, the second photodetector 19 feedback, a second servo system 20. , a logarithm 21, an integrator 22, an additional switch 23, a work switch 15 15 of the analyzed print, an analog switch 25, an amplitude selector 26, a processor 27, a characteristic input block 28.  the positive curve 9, the switch 29, the display 30, the feedback gain control regulator 31, the exposure value adjuster 32, the microtrop aperture adjuster 33.  scanning, controlled feedback amplifier 34, exponential converter 35, video signal amplifier 36, additional exponential converter 37 video aperture signal amplifier 38, white signal level coupling unit 39, white microscopic scan trajectory generator 41, teletype 42.  Interconnection of blocks and units of the device is as follows.  ,: Electron-beam tube 1, the deflection system 2 of which is connected to the sweep unit 3, and the additional deflection system 4 with the additional sweep generator 5 is optically connected through successively placed lens b, negative 8, positive 9, which are in contact at the node 10, mobile and transparent, an additional optical projection system 11, with an input of a photodetector 12, Lens 6 through an actuator 7 is controlled by a processor 27 and connected to its sixth output.  The output of the photodetector 12 is electrically connected through a logarithm 21 to the first input of the additional switch 23, the integrator 22, the switch 24 of the type of analysis-printing operation.  The output of the integrator 22 is connected to the second input of the additional switch 23, to the third input of which the seventh output of the processor 27 is connected.  The output of the additional switch 23 through the serially connected angular switch 25 to the second input of which is connected to the output of the synchronous generator 41, the amplitude selector 26 is connected to the first input of the processor 27, having feedback gain regulators 31 connected to the third output of the processor 27, regulator 32 exposure values connected to the fourth processor output.  27, aperture controller 33: a scanning microplate connected to the fourth input of the processor 27.  The first output of the input unit 28 of the characteristic curve of positive 9 is connected to the second input of the processor 27, the second output of which through the switch 29 connected to the second output of the processor 27 is connected to the display 30.  The first output of the processor 27 is connected to the first input of the controlled booster 34, the second input of which is connected to the switch 24 of the print-analysis type of operation.  The output of the controlled feedback amplifier 34 is through a series-connected exponential converter 35 and the luminance signal video amplifier 36 is connected to a modulating electrode of a cathode ray tube 1, to the focusing electrode of which is connected via a serially connected video amplifier 38 of the aperture signal and an additional exponential converter 37 eight. my processor output is 27.  To the second inputs of the video amplifiers 36 and 38, the corresponding signal outputs of the video signal level block 39 are connected by the white level, the input of which is connected to the output of the synchro-generator 41.  The movable transparent unit 10 for fixing the negative 8 and positive 9 is made in the form of a cylindrical drum or a coordinate table with X, Y interlacing.  The mobile node 10 is mounted on the shaft of the first synchronous electric motor 13 connected to the output of the first automatic control system 14, the first input of which is connected to the output of the first feedback photosensor 15 mounted on the surface of the mobile node 10 having a track with risks (not shown), Electron beam tube 1, deflection system 2, block 3 sweeps, additional deflection system 4 ,.  additional sweep generator 5, lens C with an actuator 7, an additional optical forming system 11 and a photodetector 12 are mounted on a movable carriage 16 which is mechanically connected to a lead screw 17 mechanically connected to the shaft of the second synchronous motor 18, which is connected to the second output the automatic control system 20, to the first input of which the output of the second feedback photosensor 19 is connected, and to the second input — the output of the clock generator 41; The second photosensor 19 is mounted on the shaft Vågå screw 17, Visod timing generator 41 and outputs the first and second-ib and 1U photosensors connected to respective inputs of the complementary sweep generator 5.  The fifth output of the processor 27 is connected via the scan micropath generator 40 to the sweep unit 3, whose load is the deflection system 2, and the additional deflection system 4 is connected to the output of the additional sweep generator 5.  The third input of the processor 27 is connected to the output of the synchronizing generator 41, the teletype 42 is connected to the upstream input of the processor 27, which is used to access the processor 27, which allows entering correction parameters, setting the operation mode of the microscopic scanning generator 40 and displaying the image characteristics The sensitometric parameter of positive 9 does not punched tape and digitally print.  Electronic copying device works as follows.  The switch 24 of the kind of work analysis-printing is set by the operator in the Analysis position. Positive 9 is placed on the surface of the transparent transparent unit 10, and negative 8 is placed on it.  Include the actuators of the movable node 10 and the movable carriage 16.  The electric drive of the mobile unit 10 contains the first synchronous motor 13 connected to the output of the first automatic control system 14, which controls the instantaneous rotational speed of the mobile carrier unit, the drum according to the phase error signal between the sync pulses coming from the sync generator 41 and the first photo sensor installed at the surface of the carrier node 10 and working from the scratch marks applied to the edge of the movable node, Angipogically operates the electric drive of the movable carriage 16.  The lead screw 17, rotating synchronously with the movable unit 10, displaces, along the cylindrical surface of the unit 10, the movable carriage 16 mechanically connected with the lead screw 17.  Electron beam tube 1, lens 6, additional optical forming system 11 and photodetector 12 are located on the movable carriage 16 coaxially between themselves and the perpendicularly cylindrical surface. Simultaneous activation of the movable unit 10 and the lead screw 17 linearly moving along the unit 10 carriage 16 carries out the macro-scanning of the moving unit 10 and the driving screw 17 linearly moving along the unit 10. on the negative B (the so-called spiral scan, which has found wide application in phototelegraphic and printing equipment).  However, this type of scan is anisotropic and is similar to a television scanner. In the proposed electronic copying device, there are two types of scanning at the same time: a spiral macro scan, forming a macro string, and across it, a micro scan, forming a micro discharge electron tube 1 in the plane of negative 8 - positive 9 (Fig. 2) In order to achieve isotropic macroscanning, an additional sweep generator 5 and an additional deflection system 4 are used.  Generator 5 performs the function of the following deviation generator, t. e.  At the time of the formation of the micro-scan frame, the micro-spread is stationary relative to the rotating movable unit 10.  Thus, the purpose of the additional sweep generator 5 is, firstly, to accurately align the macroscopic scanning lines, secondly, to shift the microrastra relative to the rotating movable node 10 in the direction of rotation so that the generated microrastation remains stationary relative to the negative 8 and positive 9, than the floor reaches the isotropy of the macroscopic sweep, the width of the microraster on the screen of the electron beam tube 1 is equal to the feed pitch of the lead screw 17 and is filled with the period of sync pulses taken from the photodiode The driver 19 and supplied to the input of the additional oscillator 5 sweep, the remaining inputs of which are connected to the output of the synchronous generator 41 and the output of the feedback photosensor 15.  The frame rate of the microsystem is equal to the frequency of rotation of the movable unit 10, tons. e.  the macroscopic frequency of the scan, and the frequency of the microstring is related to the ratio Wp - Mctp where OS is the aperture of the microscopic scan; E is the circumference of the mobile node 10. The frequency of the frame scan of the micro raster is synchronized by the sync pulses from the photosensor 15 feedback installed at the mobile node 10.  The microraster contains damping line and frame pulses (identical to TV-; raster), which are fed to the input of the generator 40 of the microtrip scanning trajectory from the synchro-generator 41 and to the inputs of the form of amplifiers 36 and 38 from the synchro-generator 41 through the video signaling block 39 according to the level white.  Thus, the use of an electronic learning tube 1 dl. creating in the plane a negative 8 - positive 9 microsystem with any trajectory of the exposure of the exposing light spot allows to compensate the phase shift of the mask image relative to the original corrected image in the element printing, and the same allows you to create any law of intensity distribution in the scanning spot - macroplate (for example, ring distribution - FIG.  22, which is optimal for performing a frequency-contrast correction of an element-printed image from a negative 8 to a positive 9).  The magnitude of the blurriness of the maximage created by using macro and microscanning is controlled by the processor 27 through the microtropic aperture controller 33 and through the V actuator 7 by the lens 6, which forms a macro from the entire microrash (Screen of a CRT 1, Additional optical Forming system 11 is designed for optical matching of macroscopic scanning with optical input of photodetector 12, the amount of unsharpness created by micro dot scanning when conducting an element frequency-contrast correction on the screen of the cathode ray tube 1 also controls the processor 27 through a series-connected additional exponential converter 37 connected to the eighth output of the processor 27 and a video amplifier 38, and an aperture whose output is connected to the focusing electrode 43 of the cathode ray tube 1.  To the second input of the video amplifier 38 is connected the first output of the block 39 of the video signal binding, which is connected to the output of the synchronous generator 41.  Block 39 Video signal level on the level of Beloro (negative video signal) is identical to the lock (fixation) blocks used in television, - on the black level (positive signal).  Exponential transducers 35 and 37 are designed to receive video signals that are inversely logarithmic, t. e.  perform the function of antilog.  In the analysis mode electronic.  copier works as follows.  To determine the necessary masking ratio, the exposure value, the microscopic scan aperture size, to obtain a photographic print with given gradation and frequency-contrast characteristics1 1, the gradation and frequency-contrast characteristics of the negative image are first analyzed.  To do this, a negative 8 is placed on the surface of the movable unit 10, with the switch 24 of the type of operation, the printing unit is placed in the Analysis position.  The actuators and the electron beam tube 1 are turned on, which, together with the mobile node 10, scans element-wise through lens 6, negative 8, luminous flux modulated by the transparency of negative 8, through an additional optical device 1, forming system 11 is fed to the optical input of photodetector 12, the output of which is connected to the input of the logarithmator 21, the purpose of which is to convert the signals of transparency into signals of optical density.  The use of logarithmic values in the post-processing of video signals has the advantage for carrying out electronic correction of an element-printed image: simply enough, by changing the magnitude of the gain of the logarithm signals, it is possible to change the contrast ratio of the final image on the positive 9 over wide limits.  Conducting linear and non-linear gradation correction of logarithmic signals allows the optimal image to match the characteristics of visual perception under different conditions of observation of the image during interpretation.  The output of the logarithm 21 is connected to the input of the additional switch 23, the integrator 22 and the type of analysis-print switch 24, the print contact is open in the Print position, the video signal corresponding to the integrated optical density of the scanning macro is captured from the integrator 22 output. e.  from the entire microraster created by the electron beam tube 1 on the negative 8.  This signal arrives (to the second input of the additional switch 23, the assignment of which, by commands of the processor 27, supplied to the third input of the additional switch 23 from the seventh output of the processor 27, switch to the input of the analog key 25 optical density signals from the micro and from the scanning macro, to the second the input of the analog switch 25 is connected to the output of the synchronous generator 41, the purpose of the analog switch 25 is to limit the amount of incoming information, t. e.  produce a static sample with a volume determined by the frequency of the control pulses of the voltage of the sync generator 41.  From the output of the analogue KLUCA 25, amplitude-modulated pulses of successive video signals of optical density from macro- and micro-scanning scanning slots are fed to the input of an amplitude selector 26, where they are measured by amplitude and, according to the measured amplitude, are distributed over 2 t-channels of a memory device (not shown ) processor 27, where they are counted for each of the two signals connected in series by an additional switch 23.  Thus, in the memory part of the processor 27, two histo grammes of densities from the macro and micro scanning spots are sequentially formed.  Through the switch 29, these histograms are displayed on the screen of the display 30 (FIG. 4, curves 2 "1. 2, 2), and a printout of their parameters is performed on a teletype 42. The processor 27 has two modes of operation.  The first mode.  The least squares processor 27 approximates the obtained histographs of the Haught curve H (a, 6), i.e., the functional a) is minimized by the parameters a and 6: 1 U, -N L where r is the number of quantization levels of optical density signals; N is the number of pixels; frequency of occurrence of optical density.  Pars meters a and 6 are set by the operator by accessing processor 27 via a teletypewriter keypad 44.  The transformation of the initial negative image to an image having a given distribution of optical densities I Hall (f) f is set by the operator using the 31-33 adjusters, second mode.  The processor 27 performs the alignment of the histograms, t. e.  produces such a transformation of the original histograms of the analyzed negative image, that the same probability of occurrence corresponds to all discrete values of optical density readings (for example, O - 255).  In this case, the processor 27 performs the processing of incoming information: ice: in a manner.  Each element of the analyzed negative image that has the initial optical density of DVICX.  t is assigned a new value of optical density 1). , defined by the expression D, aA 2-JHDv C4 dD, 2) where DO is the minimum value of the measured optical density of the analyzed negative 8, 2 is a CONSTANT multiplier.  Since optical density samples are discrete, the integral is in. formula (2) can be expressed by the sum lP {D.  (3) haa. 2 From the formula (3) it follows that the discrete values of the optical density of the analyzed negative image of the DUCI transform are converted by the processor 27 to a new value of O hell, using the D URENA cumulative sum X P {D youi.   Since the values of the optical density of the elements of the analyzed negative 8 from the macro and micro scanning shadows in the processor 27 are represented by the levels O - 255, the new normalized values of the optical densities of the image elements are represented by the expression 255 PlD) dD OA Dwtf 4 PCB ) dD

where I man - the maximum value of the optical density of the element of the analyzed Negtiv 8.

At the same time, the processor 27 calculates the sensitometric characteristics of positive 9; for this, a positive curve characteristic input 28 is connected to the second input of switch 29. A flat screen printed on positive 9 is inserted into the block 28, not block 28, and the optical patch of the sensor field is measured . The resulting characteristic crit. Of the positive 9 through the switch 29 is also displayed on the display screen 30, and on the TTY 42 printing device, the sensitometric characteristics of the positive 9 are printed. At the same time, the characteristic positive positive curve 9 is fed to the second input of the processor 27, where it is recorded in the storage device. Characteristic curve in the storage device and on the display screen 30. It takes its position and tilt in accordance with the photosensitivity and contrast of the photosensitive layer of positive 9, the Operator, analyzing the sensitometric characteristics of positive 9 and observed on the display of 30 display the optical density distribution of the negative 8Нмакс (), Mmmh (D) From macro and micro scanning scanning microscopes and their polarization on the axis of optical densities, as well as the form of the characteristic curve of positive 91) () and its position and tilt on the axis of ec From the positions AND, the regulator 31 of the gain circuit of the feedback circuit, the regulator 32 of the exposure value, the regulator 33 of the microscopic scanning aperture through the functional converter (not shown) of the processor 27 modifies and models the histograms of the densities of the negative 8 from macro and micro scanning tenant, and also observes the redistribution of the densities of negative 8 as the aperture of the scanning microplate changes. The controller 32 controls the offset and slope of the characteristic curve of positive 9 With respect to the Cg H exposure axis, the offset along the exposure axis determines the exposure time of the positive 9 when printing from negative 8, the change in the slope of the characteristic curve corresponds to the change in the image contrast in the future positive 9, the change in magnitude microscopic scanning and the nature of the distribution of light in the scanning macro determine the depth of the frequency-contrast correction carried out element by element printed go image.

Based on the data on the character of the distribution of optical densities in negative 8, taking into account the position and slope of the characteristic curve of positive 9, taking into account the size of the scanning microplate, specified by the regulator 33, and also taking into account the type of the micropath scanning trajectory, the processor's functional converter (not shown) 27 performs the conversion on the basis of a negative image program (1-4), the results of which are then also displayed on the display 30 via the switch 29. Modeled in the processor 27 is a curve e indicate the distribution of optical density distribution of positive photoprint densities prior to its actual preparation. The found values of the gain of the feedback circuit (masking), the exposure values, the aperture and scanning speed, the type of microscopic scanning trajectory are recorded in a memory unit (not shown) and printed on the lead typing teletype 42, then the operator switches to The seal.

The operator sets on the mobile node 10 positive 9, negative 8, switches the switch 24 kind of work analysis print to the Print position, the contacts are closed. The processor 27 is a creeper actuator 7, the lens 6 sets, in the plane of the emulsion layers of negative 8 and positive 9, the required focusing macro; scanning (mask blur), and through the generator 40, the scanning micropath trajectory forms a predetermined; type of intensity distribution in a macro. The electron-beam tube 1 is switched on, electric drives, a positive element9 cycle is performed through negative 8, the parameters of the cell are set by the processor 27. The brightness modulation of the scanning macro is specified by the processor 27 via the controlled feedback amplifier 34, the exponential converter 35, the video signal amplifier 36 modulating Electro-ray tube electrode 1. The modulation of the microplate aperture is performed by the processor 27 through an additional exponential converter 37, video amplifier 3 8 of the aperture signal onto the focusing electrode of the cathode ray tube 1. During the print cycle, the processor 27, in accordance with the set exposure value, controls the cycle of scanning through the microscope, the micropath of the trajectory 40, the block. 3 sweeps, a deflecting system 2 and a cathode-ray tube 1. For synchronous and common-mode operation of the device, the outputs of sync generator 41 are connected to the inputs of an additional generator 5 sweeps, system 14 and 20 of automatic adjustment of the analog key 25, processor 27, block 39, video signal level of white generator 40 of the scanning micropath trajectory.

The electronic copying device allows to produce a single-stage printing of film-photographic images and with a preliminary analysis of the negative image, provides the ability to automatically control the process of single-element printing of black-and-white and colorized images in accordance with an objective criterion - a histogram of image densities, providing the ability to control the intensity distribution in the scanning image. the spot reduces the anisotropy of the frequency-contrast correction carried out during printing, It allows to obtain corrected photoprints with given gradation and frequency-contrast characteristics, increases the interpretation properties of photographic prints.

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Claims (1)

ELECTRONIC-COPIER DEVICE containing a cathode ray tube, the deflecting system of which is connected to a scan unit, an optical forming system, a node for receiving negative and positive elements, a photodetector, the output of which is electrically connected through a logarithm and a type of analysis switch, to be printed with the first input of a controlled feedback amplifier connected an output to the input of the exponential converter, an analog switch connected via an amplitude selector to the first input of the processor, the first output of which connected to the second input of the feedback amplifier, and the second processor output to the first input of the switch, the output of which is connected to the display, and the second input of the switch is connected to the first output of the positive characteristic curve input block, the second output of which is connected to the second input of the processor, and the third the processor input is connected to the output of the clock generator, to which the analog key input is connected, exposure and gain controllers for the feedback circuit are connected to the third and fourth outputs of the processor ligature, characterized in that, in order to reduce the anisotropy of the frequency-contrast correction and to provide the ability to control the distribution of light intensity in the scanning spot, additional optical forming system, a deflecting system and a sweep generator, a first synchronous motor, the first automatic control system, the first are introduced into it feedback photosensor, the second synchronous motor, the second PE system _with auto-regulation, the second photosensor 8 inverse ob- communication executable an efficient mechanism of the main forming system, a scanning microspot scan generator / additional switch, an integrator, a video signal binding unit for white level, a brightness signal video amplifier, an aperture signal video amplifier, an additional exponential converter, a microspot scanning aperture regulator, a teletype, a movable carriage with a lead screw, the scan unit is connected to the output of the microspot scan path generator, the first input of which is connected to the fifth output of the processor, and the second the first input is to the output of the synchro-oscillator, while the cathode ray tube is optically connected to the photodetector through sequentially located the main optical forming system connected to the actuator connected to the sixth output of the processor, a node for negative and positive, made transparent and installed with the ability to move, and an additional optical forming system, with the cathode ray tube, the main and additional optical forming systems, and a photodetector located wives coaxially and perpendicularly to the surface of the assembly to accommodate the negative and positive connected via _(the first synchronous electric motor to the output of the first automatic control system, to the first input of which the output of the first feedback photosensor is connected, and the output of the sync generator, the cathode ray tube, main and additional deflecting systems, a sweep unit, a main optical forming system with an actuator, an additional optical forming system and the photodetector is mounted on a movable carriage connected to the lead screw connected to the shaft of the second synchronous electric motor connected to the output of the second automatic control system, to the first input of which the output of the second feedback photosensor mounted on the shaft of the screw rotor is connected, and the output is connected to the second input the clock, the outputs of the first and second feedback photosensors and the output of the clock are also connected to the inputs of an additional sweep generator, the output of which is connected to the additional itelnoy deflection system, the logarifmatora output is connected directly to the first input of the additional _switch; and its second input through the integrator, the seventh output of the processor is connected to the third input of the additional switch, the output of the additional switch is connected to the analog key input, the output of the exponential converter through a video signal amplifier of brightness, to the second input of which the first output of the video signal binding unit is connected to white to the modulating electrode of the cathode ray tube, to the focusing electrode of which is connected the output of the video amplifier of the aperture signal, the first input of which is through additional exponential converter is connected to the eighth output of the processor, and the second input - to the second output of the video block binding of white level, the input of which is connected to the clock output, the fourth input of the processor is connected microspots aperture controller scan.