SU1026111A1 - Element-by-element photo cinema picture printing device - Google Patents

Abstract

A DEVICE FOR POINTED PRINTING A CINEMA PHOTO-DAMAGE, containing an electron beam tube, the deflection system of which is connected to a scanner unit, located behind the electron beam tube, the first optical projection system, the first beam-splitting system, the film channels for the negative and counter, the second optical card and the optical card pro- grammer and the optical pro- jector pro- jector. the electron beam tube is optically coupled through the first optical projection system and the first beam-splitting system with the reference photo opryemniks whose output is coupled via a second transformer with a first logar1 tzhopom. The film channel for the optical bridge is optically conjugated through the second optical projection system and the second beam-splitting system with the input of the photo receiver, the output of which is connected via the first logarithm with the second input of the analog subtractor, the output of which is connected to the inputs of the switch of the type of analysis-print and analog key, the processor, the first output of which is connected to the first input of the switch, to the second input of which is connected the first output of the rotater characteristic block and the second output is connected to the first input of the processor, the output of the switch is connected to the input of the display, to the second input of the npioueccopa through the amplitude selector the output of the analog switch is connected, the second output of the processor is connected to the switch of the analysis-print type of work, and the third output to the first input of the controlled feedback amplifier, the second input of which is connected to the switch output of the type of analysis-printing job, the output of the feedback amplifier is connected to the input of the exponential converter, and the processor contains an exposure regulator ui and the controller of the magnitude of the gain factor, feedback circuit, and s are connected to the outputs of the synchro generator (L С scanner unit, the second input of the analog switch and the third processor input, from D and h , in order to improve the quality of decoding of the obtained images, an additional electron beam tube, a deflection system, an optically projection system, a beam splitter system, a photodetector, a logarithmizer, an analog subtractor, were introduced into it: an exponential converter, a video amplifier and a controller led additional dosage of illumination, the block selection video signal maximum optical density, teletype, adjuster setting threshold maximum optical density, the first and second sensors of the size of the raster, the first and second blocks bind the video signal on the white level and the comparison device, and additional electron beam. the tubes are located coOn and screens facing each other, with which the main first optical projection system is sequentially located, the first beam-splitting CHCTigMa, the second optical projecting

Description

a second system, a second beam-splitting system, an additional optical transmitting system, an additional beam splitting system, with an additional electron-beam tube, the deflecting system of which is connected to the scanner unit, optically coupled with a film channel for Kf HToaTHna through successively located additional optical-transmitting system and an optical projection channel system, and the output of the main analog subtractor is connected to the first input of the target signal block, the maximum optical density, to oromu input of which is connected with the fourth output processor connect to Hei / iy regulator magnitude more dosage exposure, the controller-threshold setter maximum optical density and the teletype signal output unit extracting maximum absorbance is connected to a first input of the additional analog subtractor; to the second input of which is connected via an additional, logarifmator output up to;

an additional photodetector optically connected to the screen of an additional electron beam tube through an additional optical beam splitter system, and the output of an additional analog subtractor through a series-connected additional video amplifier connected to the fifth processor output, an additional exponential converter and a second block of video linking signal according to white level to the entrance of an additional electron-beam

tubes, with the first and second raster size sensors located in front of the screens of the electron-beam tubes, connected by

the CE device is cut to the sweeps, and the outputs of the first and second blocks of video signal binding are connected to the output of the synchro-generator by the White Level and an additional video amplifier, the main electron-beam tube is connected to the output of the main exponential

The converter is through the first block of video signal binding for the white level.

one

The invention relates to professional cinematography, photography and aerial photography, in particular to sensitometry, photographic methods and processes, element by element, printing of film photographic images with automatic control of exposure.

A device is known for element-by-element printing of motion-picture images with a preliminary analysis of the distribution of optical densities in the negative and modeling using the processor of the distribution of optical densities in the future positive counter-effect, taking into account the change in the masking parameters and the exposure parameters of the print. The simulated parameters for the magnitude of the exposure and the magnitude of the gain of the feedback circuit (masking) are fixed in the processor and then used in a subsequent POE. fine print positive or counterplay 1.

The disadvantages of the device include the inability to control the sensitometric characteristics of the counterpipe, in the lower part of the characteristic curve, which does not allow purposefully to change the photosensitivity and photograph. the breadth of counter-spin for the elementary sections of the motion picture

and thereby reduces the information capabilities of the image on the counter, the completeness and accuracy of the image decoding.

The closest in technical essence to the present invention is a unit for printing by element containing a cathode ray tube, the diverting system of which is connected to a scanner unit, located behind the cathode tube first optical / projecting system, first beam-splitting system, negative, second optical Projecting system, second beam splitting. system, positive or counterplate, with the electron beam tube optically connected through the first optical system: the first projection system. and the first optical beam-splitting system with a reference photo-receiver whose output is electrically connected through the second logarithm to the first input of the analog receiver, and the negative is optically connected through the second optical projection system and the second beam-splitting system with the input of the photodetector, the output of which is electrically connected through the first logarifmator with the second input of the analog receiver; body, the output of which is connected to the inputs of the switch, sort of analysis-printing and analog key, a processor, the first output of which is connected to the first input of the switch, to the second input of which the first output of the input block of the characteristic curve of positive (counter) is connected, and the second output to ne the processor input, the switch output is connected to the display input / to the second processor input through the amplitude selector the analog switch output is connected, the second processor output is connected to the switch of the sort analysis-print job, and This output is connected to the first input of the feedback amplifier control, to the second input of which the output of the type of analysis-print switch is connected, the output of the feedback amplifier is connected to the iexof y of the exponential converter, and the processor contains an exposure regulator and a coefficient regulator amplification of the feedback circuit, and a clock unit, a second input of the analog switch and a third input of the processor 23 are connected to the output of the clock generator. The disadvantage of such a device is the insufficient quality of decoding the obtained images, since it is impossible to control and purposefully change the sensitometric characteristics of the elementary parts of the counterplate, and it is not possible to simulate and carry out the mode of elementalized supplementary counterclaim or printing. The purpose of the invention is to improve the quality of the decoding of the obtained images. . This goal is achieved by the fact that a device for printing film-by-picture images by element-by-element containing a cathode-ray tube, the opening system of which is associated with 1 block of jailTOK, located behind the cathode-ray tube first. the optical projection system, the first beam-splitting system, film channels for the negative and counter-dip, the second optical projection system, the second beam-splitting system, the electron beam tube being optically connected through the first optical projecting system and the first beam-splitting system with a reference photo receiver, the output of which is connected via the second logarithm is with the first input cm of the analogue subtractor, and the film channel for the negative is optically conjugated through the second optical projection system and the second a vegetodelitelnuyu system with the input of the photodetector, the output of which is connected through the first logarithm with the second input of the analog subtractor, the output of which is connected to the k inputs of the switch of the type of work, analysis-printing and the analog key, iipoueccop, the first output of which is connected to the first input of the switch, the second input of which is connected to the first the output of the input block is the characteristicG counter-curve curve, and the second output is connected to the first input of the processor, the output of the switch is connected to the input of the display, to the second input of the processor via the amplitude village the torus is connected to the output of the analog key, the second output of the processor is connected to a switch of the kind of work analysis-printing, and the third output is connected to the first input of a controlled feedback amplifier, to the second input of which is connected The output of the switch of the work analysis-printing, output feedback amplifier connected to the input of the exponential preobrazuvatel, while the processor contains an exposure controller and regulator of the magnitude of the gain of the feedback circuit, and to the outputs of the sync generator. connected scanner unit, the second input is key and the third processor input, an additional electron beam, tube, deflection system, optical projection system, beam splitter, photoreceiver, logarithmifier, analog subtractor, maximum converter, video amplifier and video amplifier of the additional dosed signal meter, video extraction unit, , those letayp, regulator-unit threshold maximum optical density, the first and second raster size sensors, the first and second bdoki and a video signal with a white level and a comparator device, the main and additional cathode tubes being arranged coaxially and with the screens facing each other, between which the main first optical projection system, the first beam-splitting system, the second optical beam-projecting system, the second beam-splitting system, the additional optical projection system, an additional optical beam-splitting system, with an additional electron beam tube, the deviation to the system of which is connected to the scanner unit, optically coupled to the film channel for the counter-attack through successively arranged additional beam-splitting system and optical system projecting the system, and the output of the basic analog subtractor is connected to the first input unit of the signal extractor of the maximum optical density.

To the second input of which is connected the fourth output of the processor with the dosed illumination value controller connected to it, the maximum optical density threshold adjuster and teletypers, the output of the maximum optical density extraction unit is connected to the first additional analog input. the output of the additional photoreceiver, optically connected to the screen of the additional electron-tube through the additional optical beam splitter, 15 and the output of the additional analog subtractor through the series-connected additional video amplifier connected to the processor's output , an additional exponential transducer and a second block of video signal leveling on the white level to the input of additional an electronic electron beam tube, with the first and second raster-size sensors located in front of the electron-beam tubes, respectively, connected to the scanner unit and to the output of the synchro generator, jO inputs of the first and second block of video signal blocks at the LEVEL of white and additional video amplifiers , the main electron-beam tube is connected to the output of the main exponential e converter through the first block of the video signal signal on the white level.

Figure 1 shows the functional diagram of the device for printing film-by-element images; figure 2 is a view of the implemented functions on the display screen.

The device contains an electron beam tube 1, a deflection and a tsu system l 2 || a scanning block 3, a first optical projection system 4, a first light-distributing system 5, a film channel 6 for negative (not shown), a second optical projection system. G-1U 7, second beam-splitting system 8, film channel (not shown) for counter 9, photodetector 10, first logarifmator 11, reference photoreceiver 12, second logarithmator, 13, analog subtractor 14, analog-55 key 15, amplitude selector 16 , the processor 17, the controller 18 values; the exposure, the regulator 19 value of the gain of the feedback circuit (masking coefficient) / ..60 Olok 20 input characteristic krts; howling counterplay, kviutator 21 / display 22, switchboard 23 kind of workflow analysis-printing, controlled feedback amplifier 24, exponential 5

transducer 25-, first block 26 for assigning a video signal to white levels, first sensor 27 of the raster size of the cathode ray tube 1, comparison device 28, second sensor 29 of the raster size of the second electron beam tube 30, synchronous generator 31, second deflecting system 32, third optical beam-splitting system 33, the third optical projection system 34, the third photodetector 35, the third logarithm 36, the block 37 for maximal optical density, the second analog subtractor 38, the additional video amplifier 39, Tel'nykh exponential converter 40, the second block 41 by affixing the video white level, the controller 42 further quantities dosage exposure, the controller-threshold setting unit 43 and the maximum absorbance teletype 44

The interconnection of blocks and units of the follower device: electron beam tube 1, the deflecting system 2 of which is connected to the scanner unit 3, is optically connected through the first optical forming system 5, the negative second optical reference system 7, the second beam-producing system 8 with the counterclaim. In the oracle the electron beam tube 30, the SECONDARY deflecting system 32 of which is connected to the scanner unit 3, is optically connected via the third beam-separation system 33 and the third optical projecting system 34 with counterplugging tubes of the electron-beam tubes 1 and 30 are also optically connected with the corresponding sensors 27 and 29 raster sizes that are installed at the screens. The second beam-splitting system 5 removes a part of the light flux from the cathode ray tube 1 to the optical input of the reference photodetector 12, the output of which is connected to one of the analog inputs via the second logarithm 13. A reader 14. A second light-dual system B leads a part of the light of a fresh stream, promoted by the transparency of negative 6, to the optical input of the photodetector 10, whose output through the first logarithm 11 is connected to the second input of the analog subtractor 14. The output of the analogue reader 14 is connected simultaneously to the inputs of the analog switch 15, to the second input of which you connect the output of the synchronous generator 31, the switch 23 of the type of work analysis print and the block 37 for extracting the signal of maximum optical density. The output of the analog switch 15 through the amplitude selector 1b (performs the functions of a statistical sampling unit) is connected to the second input of the process:

Copy 17, to the first input of which the output of the counterpart 9 characteristic curve input unit 9 is connected. The second output of the block G) through the switch 21 connected to the first output of the processor 17 is connected to the input of the controlled feedback amplifier 24 (by gain), the second input which is connected to the third input of the processor 17, and to the third input of the amplifier 24 is connected the output of the synchronous generator 31. The output of the controlled feedback amplifier 24 through the exponential converter 25 and the first block 26 of video signal binding on the level of The unit used in TV monitors is connected to the input of the electron beam 3 of the tube 1. To the second input the unit: a; 26 are connected to the output of the synchronizer's output 31. The processor 17 is connected to the printing device 44 with a keyboard: and contains four regulators: the regulator 18, the exposure magnitude, the regulator 19 of the feedback circuit gain — the masking coefficient the torus 42 is the magnitude of the additional dosed illumination and the controller setpoint 43 of the maximum optical density threshold. The third input of the processor 17 is connected to the clock input of the synchronous generator 31. The fourth output of the processor 17 is connected to the second input of the signal absorption unit 37 of the maximum optical density, the output of which is connected to one of the Btoporo inputs of the analog subtractor 38, to the second input of which is connected through the third logarithm 36 the output of the third the photodetector 35, optically coupled through the third beam-splitting system 33 to the screen of the second cathode-ray tube 30. The output of the second analog subtractor 38 is connected to the input of the additional video The amplifier 39, to the second input of which the fifth output of the processor 17 is connected, and to the third input the output of the synchronous generator 31. The output of the additional video amplifier 39 through the additional exponential converter 40 and the second block, 41 video signal levels for white levels, to the second input of which the output sync generator 31, is connected to the input of the second cathode-ray tube 30. The output of the first sensor 27 of the size of the raster of the cathode-ray tube 1 and the output of the second sensor of the sensor 2 9 of the size of the raster of the second cathode-ray tube 30 through the device The comparison unit 28 is connected to the unit 3 sweeps, the output of the clock 31 is connected to the second input of the KOTopoi.

Conducting elemental printing of film photographs is carried out as follows.

Select the type and axis number of the counter-film. The densitogram is printed on a counter on a standard sensitometer, for example, a CS-2m (not shown). Then, a chemical photographic processing of the obtained sensitogram is performed under standard conditions in a filling machine (not shown) with the specified technological parameters (time of temperature, gamma). A sensitized sensor (not shown) is inserted into the characteristic and curved counter input unit 20, which measures the optical densities of the sensitogram fields and, through the switch 21, displays the density readings as a graph (Fig. 2, curve 1.1) on the display screen 22, the resulting characteristic curve is entered a memory block (not shown) of the processor 17. The characteristic counter-curve of the memory block of the processor 17 and on the display screen 22 occupies the position and tilt in accordance with the calculated light values 5 Sensitivity and contrast ratio have dupe. At the same time, an analyzed negative on the applied glass (not PoKa3atto) is installed between the first beam-splitting system 5 and the second optical projection system 7. The electron beam tube 1 is switched on and controlled through the deflecting system 2 by the scan unit 3. The electron beam tube 1 scans the negative through the first optical projection system with a 5-spot constant luminance, constant aperture and constant speed — the sweep frequency is constant. Part of the luminous flux, promsdunirovannaya negativnymi negatives, through the second optical projection system 7 and the second light-signaling system 8 enters the optical input photoreception-; nick 10, from the output of which the video signal of transparency through the n; a digital logarifier 11 is fed to one of the inputs of the analog subtractor 14; the second input of which receives the mask reference video signal from the output of the reference photodetector 12 optically connected to the screen of the electron-beam tube 1 through the first optical projection system 4 n the first optical beam splitter Hyjo system 5, through the second logarithm 13. The judgment of the reference photodetector 12 and. the second logarithm 13 consists in obtaining a mask reference signal used to obtain the true signals of the optical density of the negative without the superimposed electronic aski formed on the screen of the electron-beam tube 1 in the printing process, as well as used for

compensating for the unevenness of the glow of the screen across the field, which ultimately results in increasing the quality of the analysis and element-by-element printing of the photographic still image onto a photographic carrier. The use of logarithmic values in the subsequent processing of video signals of an image has an undoubted advantage for carrying out electronic correction of an image print item by element: Simply changing the gain of logarithmic video signals, changing the contrast ratio of the reproduction characteristics of the system} carrying out linear and nonlinear gradation correction of logarithmic video signals, allowed optimally match the characteristics of an liziruemog element by element and the printed image with the visual characteristics under different conditions of observation images. The purpose of the analog subtractor 14 is to implement function 1.

neg + pillars support nonprocessor 17 sets the switch 23 kind of work analysis print to the analysis position. From the output of the analog subtractor 14, the video signal of the optical density of the analyzed Negative is fed to the input of the analog switch 15, to the second input of the KOtroi igtal voltage from the synchro generator 31 comes. The purpose of the analog switch 15 is to limit the volume of the incoming information, i.e. to produce a statistical sample with the volume determined by the frequency of the control pulses of the voltage of the clock generator 31. From the output of the analog switch 15, the amplitude-modulated I1 pulses of the video signal of optical density arrive at the input of the amplitude The selector 16, where measured in amplitude and in accordance with the measured amplitude, is distributed on the memory channels of the device (not accessed) of the processor 17, where p is the number of them. Thus, in the storage part of the processor 17, a histogram of optical densities is formed, which, as a graph, through the switch 21 is displayed on the screen of the display 22 (Fig. 2, curve 1.2). on the display screen 22, the nature of the distribution of optical densities in the negative (Fig. 2, curve 1.2) and its position on the D axis (gH) of the optical densities, as well as the type and slope of the characteristic countertrap curve and its position

on the axis of exposures tgH fkg.2, curve 1.1), regulator 19 of the magnitude of the gain of the feedback circuit - masking through a functional converter (not noKa3aH) j

processor 17 alters and simulates a histogram of densities of the element-by-element masked negative (figure 2, curve 1.2), and adjusting the value 18 of the exposure through the functional converter of processor 17 sets the offset of the characteristic curve of the counter ratio relative to the axis of the exposures (figure 2, curve 1.1). The shift of the characteristic curve along the axis of the exposure determines the exposure time of the element-by-element exposure — the exposure, and the change in the slope of the curve (specified by the controller 19 and the controller 42) corresponds to the change in contrast

0 images in the counter. Next, based on the operator-modeled data on the distribution of optical densities in the Layer of the masked negative (Fig. 2, curve 1.2) and taking into account the position of the characteristic curve () (Fig. 2, curve 1.1), the functional converter of the processor 17 performs the following transformation of the histogram of future densities counterclamp (Fig. 2, curve 1.3), which is also output to the display screen 25 through the switch 21.

The processor 17 has two modes of operation.

The first mode. Functional Prech

5, the processor of the processor 17 approximates the obtained histogram of the negative by the Gaussian curve M ((,, b)), using the least squares method, i.e. the functional is minimized by the parameters L and Cr

|, B-.,

where g is the number of quantization levels 5 of the video a-ki optical density;

N is the number of picture elements, and; - frequency of occurrence of value

optical density equal to; The parameters L and (5 are set by accessing the processor 17 via the teletype 44. The conversion of the original negative image to an image having the OUT Density distribution of optical density N (k, (3) 5 is set using adjustments 18. And 19..,

Second mode. The functional converter of the processor 17 aligns the histogram 1F1, that is, it produces a conversion of the initial histogram of the analyzed negative such that all discrete values of optical density readings (for example, for a particular case from 0 to 255) 5 correspond to the same probability . In this case, the processor 17 processes the incoming information according to the following algorithm: each element of the negative image being analyzed that has the original optical density RIS is assigned a new optical density value DI, which is determined by the expression goAA Jp (OArH1G1, (2) where DO is the minimum the value of the measured optical density of the analyzed negative constant factor. Since the optical density is discrete, the integral in formula (2) can be expressed by the sum Dj A - 1 piDi Gz; / From the formula {3} it follows that the discrete optical density values of the analyzed NegatiBaD j. image are converted by the processor 17 to the new value Back using the CALCULAR CyMNfel computed processor 17. The values of the optical density of the elements of the analyzed negative are from normal values from 0 to 255, the new normalized wholesale values The elemental pixel densities are represented by an expression. p 255 p (tiUD ass- Dn j ptDldB whereEtech is the maximum value of the optical density of the element of the analyzed negative. At the same time, the processor 17 makes calculation of the sensitometric characteristics of the coin and their printout on the teletype 44. The parameters of the additional element-by-element dosed illumination of the counter-dip are simulated. Modeling of the transformational counterpart transformations as a result of conducting additional element-by-element dosed illumination takes place in processor 1 in the following way. The task of controlling the processor of additional dosed illumination is to calculate the values of adjustable process parameters that ensure the achievement of a given characteristic countertrap curve in the initial part. The generally accepted sensitometric characteristics change, as a rule, interconnectedly, due to a relatively small change in the shape of the characteristic curve when using conditions of an additional elemental dosage illumination. Mathematical modeling of the characteristic curve of the counterplate and the process of additional element-by-element dosage illumination in processor 17 is based on the fact that negative and counter-reference cinema photons. The materials contain a light absorbing substance, which is decisive for modeling the process of illumination, as at low doses of exposure conditions of additional element-by-element dosed illumination, due to a significant change in the amount of illumination in the depth of the layer and taking into account By using a scanner of a light source to carry out the illumination (the phenomenon of non-reciprocity), it is primarily possible to simplify the modeling of the bird-physical part of the photographic process of additional element-by-element dosage illumination (we consider the chemical-photographic process to be unchanged and specified by the operating parameters). The processor 17 modulates the entered integral characteristic curve of the counterpit sensitogram (FIG. 2, curve 1.1 / dl for the photosensitive layer in depth using the following formula: + SHw) Q-i. + tSH "e. PG de Q, -, 5, And emulsion parameters related to the emulsion layer itself / parameters, determined by irrigation technology of emulsion layers — a parameter determining the concentration of the photosensitive substance in the emulsion / thickness of the watered layer, i-m redemption rate a photosensitive layer, defined with respect to the radiation of a standardized spectral composition, for example, a source with a given color temperature, S — light sensitivity of the layer; B is a veiling parameter, Q, is a parameter characterizing the width of the photosensitivity distribution function of emulsion grains. The above formula (5) models the real characteristic curves of the photosensitive layer of the counterplate, in which it is photographically. The cue effect is expressed by the amount of a substance that is capable of manifestation as a result of the additional element-by-element metered exposure. When modeling in the processor 17 the process of metering with the input of the values of the parameters listed with teletype 44, it is worth noting the following: - Increasing the parameter E, which characterizes the thickness of the photosensitive layer, entails an increase in the contrast ratio J and the maximum optical density Imoix . . - an increase in the light redemption index P by the emulsion layer leads to an increase in the photographic latitude U and a simultaneous decrease in the contrast ratio U; - a decrease in the parameter G leads to a decrease in the curvilinear sections of the characteristic curve}, - an increase in the parameter of the veiling B leads to a decrease in the gradient of the characteristic curve in the smelling section. Change (vary) the parameters mentioned above and change the position of the regulator 42 to the amount of additional dosed illumination, to achieve the desired form of the lower part of the characteristic counter-curve. Set the threshold by the setting regulator 43 for the maximum optical density threshold above which the illumination is performed and below not produced, i.e., an additional, element-wise, dosed illumination is produced only for TeJj negative image areas, the maximum optical density of the KOTQfiwx is that of the set threshold ( It is important to establish several rtujraroBs and, for each threshold, its own value of additional dosage illumination.) Thus, when an elemental negative is carried out on a counterclaim with the correction of the printed image, only at specified points in the image the sensitometric characteristics of the photosensitive counterparty are deliberately changed .pas. Perform a printout of new sensitometric characteristics, counterparts, obtained as a result of modeling in the processor 17, deduced from the modeled characteristic curve (figure 2, curve 1.1) on the display screen 22. If the operator satisfies the result of the survey, the positions of the controllers 18, 19, 42 and 43 are fixed and the processor 17 switches the switch 23 of the type of analysis-print job to the print application, if not satisfied — the operator re-simulates and changes some parameters until the desired result is achieved. I Produces a print mode with simultaneous additional elementalized dosage illumination. Install on the applied glass. (Not shown) counter. Include cathode tubes 1 and 30,. The rasters of which are measured by the X and Y coordinates of the raster size sensors 27 and 29, the outputs of which are connected to the inputs of the comparison device 28, which controls the unit 3 sweeps so that the rasters have ODig geometric dimensions / (here there are no strict requirements Since the aperture of the scanning spot when printing in the plane of photographic materials is 2 mm and higher, it is determined by the parameters of the frequency-contrast correction determined from tables and graphs (not shown). The electron-beam tubes 1 and 30 are set screens facing each other, produce element-wise exposure of the counter electron electron beam tube 1 through the first optical projection system 4, the first optical beam splitting system 5, the negative, the second optical projecting system 7, the second beam splitter 8, and the second electron beam tube 30 through the third optical, beam-splitting system 33 and the third optical projection system 34, and the scanning spots of the electron-beam tubes 1 and 30 simultaneously and simultaneously exhibit the same element The counter (plot) of the counterpipe, the electron-beam tube 1 is on the side of the emulsion layer of the counterpipe, and the second electron beam tube 30 is on the side of the base of the counterpipe, the second electron beam tube 30 is turned on only at those times when the optical density of the elementary portion of the negative is higher than the one specified by the regulator 43 thresholds. The intensity of the scanning spot of the electron-beam tube 1, determined by the parameters of the unit-by-element printing, calculated by the processor 17, is controlled through the series-connected first video signal binding unit 26 according to the white level (identical to that used in television, but the level is white). that the transformations are carried out with negative video signals, and in television, with positive signals, and therefore the reference is “correctly connected to the control electrode (not shown) of the 1.exponential circuit a solver 25 (log.or.), a controlled feedback amplifier 24, to the first input of which is connected the output of the switch 23 of the type of work, analysis-printing in position, and to the second input - the third output of processor 17. At elementary) The elementary sections of the negative are exposed at a maximum optical density, exceed the specified threshold. The threshold is determined as a result of modeling and set by the knob controller 43 threshold through process 17, the fourth output of which is connected to the second input of the block 37 selecting the maximum optical density (adjustable selector with controlled threshold), the output of which is connected to the first input of the second anode subtractor 43, to the second input of which is connected through a logarithm 36, the output of the third photodetector 35, optically connected to the screen of the second electron-beam tube 30 through the third optical beam-splitting system 33. Purpose of the third photodetector 35 ,: the third logarithmizer 3 € and the second analog subtractor 38 coctO to compensate for the unevenness of the screen of the electron-beam tube 30. The output of the second analog subtractor 38 via an additional video receiver 39, the second exponentiated 11 converter 40 and the second block 41 of the video signal binding the white level is connected to the control of the electrode (not shown) of the second cathode ray tube 30. To the second input of the additional video cable 39 and the fifth output of the processor 17 is connected, which in In accordance with the calculated synositometric parameters of the counterplay and simulation results, the additional video amplifier 39 determines the intensity of the scanning spot of the second electron-beam tube 30, producing elemental additional metered illumination of the counterplot parts on which the negative sections with optical density are above the specified threshold. . Chemical and photographic processing of the counterpipe is carried out under standard conditions on a filling machine (not shown) with specified technological parameters. Then, a print run of positives is printed from the element-adjusted Correctype. To ensure synchronous and consistent operation of the device, the outputs of the sync generator 31 are connected to the inputs of an analog switch 15, a scanner unit 3, a processor 17, a controlled feedback amplifier 24, an additional video amplifier 39, a first unit 26 and a second unit 41 for signal signaling white. The proposed unit for element-by-element printing of film images based on an objective analysis of the distribution of negative optical densities, modeling was decided by an additional yo-element cell dose by irradiation in the elementary areas of the photosensitive layer of the counter-film, allows for autoalatal control of the process of element printing by the application of the application by the application by the application by the application with the speed limit of the application by the application by the application by the application by the application with the application of the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application by the application with the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application by the application of the application. Optical densities, which improves the quality / image decoding, increases productivity by exclusion of test printing from the process, exceptions to repeated seismic tests. Using the mode of additional element-by-element dosage illumination in the case of element-by-element printing on the counterplate is equivalent to the use of two counter-film with different sensitometric parmeters, with one of the counter-films having the optimal parameters for darker, more dense HbDt / uch; film images and images in negative, and the second - optimal Sensitbmetric parameters for bright, less dense sections, which increases the information capabilities of the counterplay, increases the completeness and accuracy of the detection and images. The proposed device, in comparison with the basic device ESCOR, allows to change the sensitometric characteristics of the counter in the elementary areas of the image.

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Claims (1)

SUBSTANCE: device for photo-element printing of photographic images, comprising a cathode ray tube, a deflecting system of which is connected to a scanning unit, a first optical projection system, a first beam-splitting system, film channels for negative and counter-type, a second optical projection system and a second optical projection system, located behind the cathode ray tube optically coupled through a first optical projection system and a first beam splitting system with a reference photodetector com, the output of which is connected through the second logarithm to the first input of the analog subtractor, and the film channel for the negative is optically coupled through the second optical projection system and the second beam splitter system to the input of the photodetector, the output of which is connected through the first logarithm to the second input of the analog subtractor, the output of which is connected to inputs of the switch of the kind of work analysis-printing and an analog key, a processor whose first output is connected to the first input of the switch, to the second input of which is connected rvy rvoda block output characteristic curve dupe ^. and the second output is to the first input of the processor, the output of the switch is connected to the input of the display, the output of the analog key is connected to the second input of the processor through the amplitude selector, the second output of the processor is connected to the switch of the kind of analysis-print operation, and the third output is to the first input of a controlled feedback amplifier communication, to the second input of which the output of the switch of the kind of work analysis-printing is connected, the output of the feedback amplifier is connected to the input of the exponential converter, while the processor contains an exposure controller and regulator of the magnitude of the coefficient, gain of the feedback circuit, a S a scan unit, a second input of an analogue key and a third input of the processor are connected to the outputs of the synchro generator, * which is the same,% in order to improve the quality of interpretation of the obtained images, · an additional cathode ray tube, a deflecting system, an optical projection system, a beam splitter system, a photodetector, a 'logarithm, an analog subtractor,' 'an exponential converter, a video amplifier and a value controller are introduced into it,' g there are additional dosed illumination units, a maximum optical density video signal isolation unit, a teletype, a maximum optical density threshold adjuster-regulator, first and second raster size sensors, the first and second video signal reference units ^ according to white level and a comparison device, the main additional electron beam. the tubes are arranged coaxially and with screens facing each other, between which the main first optical projection system, the first beam splitter system, the second optical projection system, the second beam splitter system, the additional optical projection system, the additional beam splitter system, and the additional cathode ray tube, the deflecting system of which is connected to the scan unit is optically coupled by a film channel for the contotype through a series of additional LED system and an optical projection system are arranged, and the output of the main analog subtractor is connected to the first input of the maximum optical density signal extraction unit, the second input of which is connected to the fourth processor output with an additional dosed illumination regulator connected to it, a threshold setting regulator maximum optical density and teletype, the output of the maximum optical density signal extraction unit is connected to the first input nogo analog subtractor, to the second input of which is connected via optional. the logarithmator is the output of an additional / additional photodetector optically coupled to the screen of the additional cathode ray tube through an additional optical beam splitter system, and the output of the additional analog subtractor is connected through an additional video amplifier connected to the fifth output of the processor, an additional exponential converter, and a second video signal binding unit according to the white level the entrance of an additional cathode ray tube, and in front of the cathode ray tubes ok, the first and second raster size sensors are located, connected through the comparison device to the base of the sweep, and the inputs of the first and second blocks of video signal binding by the level of white and additional video amplifier are connected to the output of the sync generator, the main cathode ray tube is connected to the output of the main exponential converter through the first video signal alignment unit according to white level. '