SU898376A1 - Electronic copying apparatus - Google Patents

Description

() ELECTRONIC COPYING DEVICE

The invention relates to photography, in particular, to devices for photographic printing with automatic exposure control. Electron-copying devices consisting of a cathode ray tube (CRT), the deflecting system of which is connected to the scanner unit, are successively located on the CRT of the optical projection system, applied glass for placing a negative and a positive photomatrix, a photomultiplier tube connected with CRT through a feedback amplifier. Masking when printing on these devices is carried out by creating an unsharp brightness mask using amplitude modulation of the exposure, i.e. by changing the brightness of the scanning spot in the elementary areas of the negative l. The disadvantage of such devices is the need for the operator to produce several test photographic prints at different values of the masking coefficient and different values of the exposure to obtain a photographic print with predetermined gradation characteristics. The number of samples depends on the experience of the operator, and the accuracy of determining the magnitude of the masking coefficient and the magnitude of the exposure is determined on the basis of a subjective assessment of the resulting image on the best (subjective) print. The presence of samples and a subjective image evaluation factor reduces labor productivity and does not provide prints with predetermined gradation characteristics, as a result of which the photographic image quality, the completeness and reliability of its interpretation are reduced. The closest technical solution to the present invention is an electron-copying device containing a CRT, a deflecting system of which is connected to a scanner unit, an applied glass located behind the CRT to accommodate a negative that is optically connected through the beam-splitting system and the optical projection system with a screen for placement of a positive photographic material, a photomultiplier tube optically coupled to the beam-splitting system, and electrically through serially connected logarithmic converters An alternator, an analog switch and an amplitude selector — with the first input of the analyzer-optimizer with feedback controllers and in the exposure mode, the first output of the analyzer-optimizer is connected to the first input of the feedback amplifier, to the second input of which the type of job is connected. and the second output of the analyzer-optimizer is connected to the first input of the switch, the output of which is connected to the graphic display, and the second input is connected to the first output of the block for building the characteristic curve of positive photographic material the second output of which is connected to the second input of the analyzer optimizer, the third input of which is connected to the first output of the clock generator, the second output of which is connected to the analog key, and the third to the scanner unit 21. However, when performing photo printing with masking, the parameters of the contrast contrast are dependent on the degree of unsharpness and contrast, apply my mask. On these electronic copying devices, the degree of unsharpness of the mask is determined by the dimensions of the scanning spot, and the krast of the mask is determined by the magnitude of the feedback coefficient. The degree of unsharpness and the level of feedback coefficient are interrelated. So, for example, reducing the size of the scanning spot (mask unsharpness) allows increasing the feedback ratio (mask contrast), and increasing the size of the scanning spot (mask blurring) requires reducing the feedback ratio (mask contrast). When printing photos from highly contoured negatives on these electronic copiers, it becomes necessary to maximize the feedback coefficient, which leads to a violation of the optimal ratio between blurring and contrast of the mask. At the same time, on photographic prints obtained with such printing parameters, undesirable distortions arise in the form of false contours to underline the boundaries of area objects, the dimensions of which exceed the scanning area. On the masked print, the edges of the dark details of the image are transmitted with increased density, and the less dense parts of the background bordering the detail become lighter. For a light detail on a dark background, the opposite effect is obtained. As a result, the photographic quality and the deciphering properties of the images taken are reduced. In addition, such electron-copying devices do not allow an optimal frequency-contrast correction of a photo image during the printing process, taking into account the non-linearity of the photographic process of reproduction and the process of visual perception of image details with a high spatial frequency. The purpose of the invention is to improve the quality of the photo image. The goal is achieved by the fact that in an electron-copying device containing a CRT, the deflecting system of which is connected to the scanner unit, the applied glass behind the CRT is used to accommodate a negative that is optically connected through a beam-splitting system and an optical projection system with a screen for placing positive photo material, a photomultiplier tube optically coupled to the beam-splitting system, and electrically through a series-connected logarithmic converter, an analog key and amplitude selector - with the first input of the analyzer-optimizer with feedback controllers and holding time, the first output of the analyzer-optimizer is connected to the first input of the feedback amplifier, to the second input of which the type of job switch is connected Print - analysis, and the second output of the analyzer is the optimizer is connected to the first input of the switch, the output of which is connected to the graphic display, and the second input is connected to the first output of the block for building the characteristic curve of the positive photographic material, the second output of which It is connected to the second input of the analyzer-optimizer, the third input of which is connected to the first output of the synchronous generator, the second output of which is connected to the analog key, and the third output to the scanner unit, introduced an exponential amplifier, a time modulation unit, the second and third switches and an inverter, the type of operation switch Printing - analysis is connected to the output of a logarithmic converter, and the output of the feedback amplifier is connected to the input of an exponential amplifier, the output connected to the first inputs of the second and third of its switches, the second inputs of which are connected to the fourth output of the clock generator, the first output of the second switch is connected to the focusing electrode of the CRT and the second output is connected to the focusing electrode of the CRT via an inverter, the first output of the third switch is connected to the CRT modulator, and the second output is through a time block the modulation is connected to a sweep unit; the third inputs of the second and third switchboards are connected respectively to the third and fourth outputs of the analyzer-optimizer. FIG. 1 is a block diagram of the device; in fig. 2 shows an example of the functions analyzed by the operator on the graphic display screen when determining the analysis process. The electronic copying device contains a scanning light source of a CRT 1 (it is possible to use a scanning laser beam), a deflecting system 2, a block of 3 sweeps, an applied glass 4 for placing a negative 5, a dividing system 6, a projection system 7, a screen 8 for placing a positive photographic material 9 , photomultiplier 10, logarithmic converter 11, analog key 12, amplitude selector 13 analyzer optimizer 14, feedback amplifier 15, first switch 16, graphic display 17, building block 18 character of a positive photomaterial's curve. 9. sync generator 19. work class switch 20 Printing - analysis, feedback value controller 21, exponent value control controller 22, exponential amplifier 23, second switch 24, third switch 25. inverter 2b, block 27 time modulation. Electronic copying device operates as follows. First, the necessary magnitude of the masking coefficient is determined and the magnitude of the exposure is needed to obtain a print with a specified gradation characteristics. To do this, negative 5 is set to the application cost 4, switch 20 Print analysis is set to the analysis position, CRT 1 is turned on and the scanner unit 3, the negative image is scanned with a running spot of constant luminance with a minimum aperture and at a constant speed. Part of the light flux transmitted through the negative 5 is diverted by the beam-splitting system 6 to the photomultiplier 10, the output of which is an electrical signal proportional to the transparency of the negative 5. is fed to a logarithmic converter 11 that converts it to an optical density signal that is fed to the input of the analog switch 12 where its amplitude values are fixed at the moments of time determined by voltage pulses arriving at the second input of the analog switch 12 from the clock generator 19 Purpose of analogs key - limit the amount of incoming information, i.e. perform statistical sampling with a volume determined by the frequency of the control pulses of the voltage of the synchronous generator 13; From the output of the analog switch 12, amplitude modulated pulses are fed to the amplitude selector 13, where the electrical optical density signals are measured at the amplitude and, according to the measured amplitude, are distributed through the channels memory analyzer optimizer k, where their numbers are counted. Thus, a histogram of the negative optical density distribution is formed in the memory portion of the device 14. Via switch 1b, this histogram is displayed on the graphic display 17. The second input of the switch 16 is connected to the positive photomaterial characteristic curve building block 9. The resulting curve is output through the switch 16 to the graphic display screen 17 and simultaneously to the second input of the analyzer-optimizer 14, where it is recorded in the stopping device. The characteristic curve in the memory of the analyzer-optimizer C and from the display screen 17 takes up its position in accordance with the photosensitivity of the positive photographic material 9. The operator, observed on the display screen, is an optical distribution pattern. the density N (D) of negative 5 (curve 1, fig. 2) and the position on the axis of the optical surfaces of Ots, as well as the characteristic curve of the positive photographic material D (g N) and its position on the axis of the exposures (curve 2), By a factor 21, the feedback coefficient 15 through the functional converter of the analyzer-optimizer 1t changes and models the histogram of the distribution of the optical densities of the masked negative image (curve 1), and the controller 22 of the exposure value through the functional converter of the analyzer-optimizer 14 sets the offset of the characteristic curve along the axis of exposure (curve 2). The offset of the characteristic curve along the exposure axis determines the scan time (exposure) when printing from a negative. Based on the obtained data of the simulated distribution of optical densities of the masked negative (curve 1) and taking into account the characteristic curve (curve 2), the functional converter of the optimizer analyzer 1t transforms the distribution of optical densities of negative 5 into the distribution of optical densities on the future positive print N (py ) (curve 3) which is displayed on the display screen 1. The type of histogram of the density distribution on the positive print (curve 3 and 3) is determined by the position of the regulator 21 feedback of the magnitude of the exposure control 22, which corresponds to the specified masking, as well as the appearance and shift of the characteristic curve of the positive photographic material 9- The simulated positive optical density distribution (curve 3) in the optimizer analyzer 14 (curve 3) gives the operator an averaged information about the gradation characteristics of the print before it is obtained. The found values of the magnitude of the masking coefficient and the magnitude of the exposure are recorded by the analyzer optimizer k, which, based on the selected value the masking coefficient determines the scan spot aperture, i.e. necessary mask blur.

Claims (2)

The electronic copying device can be printed by scanning a negative with a constant-aperture spot, the value of which is determined by the analyzer-optimizer in accordance with the chosen masking coefficient value, by scanning with a variable aperture spot for performing a contrast-frequency image correction. intended for subsequent visual (subjective) analysis or for subsequent objective analysis by microphotometry. When printing a constant-aperture spot from the analyzer-optimizer k, via the second switch 2k, a corresponding constant electrical signal is applied to the focusing electrode of the CRT 1, the value of which determines the spot scanning aperture. When printing a variable spot to perform frequency-contrast correction of images intended for subsequent visual analysis, the aperture of the scanning spot increases in accordance with the increase in optical density of the analyzed elementary areas of negative 5. This printing mode allows to increase the contrast of fine details in the shadows of the image. In this printing mode, the analyzer optimizer 14 determines the range of variation of the scan spot aperture in accordance with the masking coefficient and the optical density range of the positive print (curve 3). The variation of the aperture of the scanning scan is performed by a signal from the feedback amplifier 15 connected via an exponential amplifier 23, the output of which is connected through the second switch 24 to the focusing electrode of the CRT 1, and the brightness value of the scanning spot is also set by signals from the amplifier 15 feedback through the exponential amplifier 23 and the third switch 25 connected to the modulator of the CRT 1. In addition, the masking of high-contrast negatives can be performed by signals from the feedback amplifier 15 through 9898 exponential a power amplifier 23 and a third switch 25 connected to the time modulation unit 27, which controls the sweep unit 3. In this case, depending on the density of the analyzed elementary negative segment, the scanning speed changes. To perform frequency-contrast correction of images intended for objective analysis, as well as to improve the transfer of fine details in the highlights and shadows of the image, the change in the size of the scanning spot aperture is relative to the average optical density of the positive print determined by the optical density analyzer histogram of optical density distribution positive imprint (curve 3). At the same time, in the process of printing, via a feedback signal through the second switch 2, connected with the focusing electrode of the CRT 1, the scanning spot aperture increases as the optical densities of the negative elementary sections increase to a certain value corresponding to the average optical density of the positive print (curve 3). and for optical densities exceeding the optical density of the negative corresponding to the average optical density of the positive imprint, the aperture of the scanning spot decreases with an increase in the optical density of the elementary part of the negative, while the second switch 2k switches the control electrical switch from the analyzer optimizer 1 signal aperture value to the input of the inverter 2b, which is connected to the focusing electrode of a CRT 1. After performing a negative analysis and determining the magnitude of the feedback coefficient and the magnitude of the exposure in the process of printing with a variable aperture of the scanning spot or with a constant aperture, but different from the aperture of the scanning spot, which was used to analyze the negative, can change the parameters of the histogram of the distribution of optical optical densities of positive (curve 3 ). In order to prevent this, before printing, it is necessary to carry out a control, in which the ansliz is performed when translating switch 10 of the type of work into the Print position. In this scan, negative 5 is performed in accordance with the parameters defined for obtaining prints with predetermined gradation characteristics and a certain frequency-contrast correction. Observing the nature of the distribution of the optical densities of the positive N (0) (curve 3)) on the display screen 17, the operator may weigh up and adjust the necessary print parameters. To improve the masking quality, the electrical signals corresponding to the transparencies of negative 5 are logarithmized in block 11 and received through a work mode switch 20 Print - analysis to the input of feedback amplifier 15, from the output of which, for modulating a CRT beam, 1, signals arrive through an exponential amplifier 23 For synchronous operation, the second switch and the third switch 25 are connected to the synchronous generator 19. The proposed electronic copying device allows, based on an objective assessment of the gradation characteristics, the outcome th negative, positive sensitometric properties of the photographic material prior to receive the distribution histogram of the optical densities of positive future print on which can be determined a priori its gradational characteristic. At the same time, the set masking coefficient is the initial parameter for automatically determining the mask blur level (the size of the scanning spot aperture). In addition, the device allows, when printing, to perform masking with variable blur parameters, which ensures the elaboration of fine details of the image, .. for subsequent subjective or objective analysis of photographs. An electronic copying device comprising a CRT, the deflecting system of which is associated with a scanner unit, an applied glass behind the CRT for accommodating a negative, which is optically coupled through a beam splitter and an optical projection system with a screen for accommodating a positive photographic material, a photomultiplier optically coupled to the beam-splitting system, and electrically through serially connected logarithmic converter, analog key and amplitude selector - with the first input of the analyzer-optimizer with feedback controllers and hold time, the first output of the analyzer-optimizer is connected to the first input of the feedback amplifier, to the second input of which the work type switch Print - analysis is connected, and the second output of the analyzer - optimizer is connected to the first input of the switch, the output of which is connected with the graphic drive, and the second input - with the first output of the block for constructing the characteristic curve of a positive photometric, the second output of which is connected to the second input in the analyzer optimizer, the third input of which is connected with the first output of the clock generator, the second output of which is connected to the analog key, and the third output to the scanner unit, which is different from the fact that, in order to improve the quality of the photo image, 89 an amplifier, a time modulation unit, a second and a third commutator, and an inverter, the type of work switch Printing analysis is connected to the output of a logarithmic converter, and the output of the feedback amplifier is connected to the input of an exponential amplifier, Connected to the first inputs of the second and third switches, the second inputs of which are connected to the fourth output of the clock generator, the first output of the second switch connected to the focusing electrode of the CRT, and the second output connected to the focusing electrode of the CRT via an inverter, the first output of the third switch is connected to the CRT modulator and the second output through the time modulation unit is connected to the sweep unit, the third inputs of the second and third switches are connected respectively to the third and fourth outputs of the analyzer-optimal mash. Sources of information taken into account in the examination 1.Photogrammetni with 1 ngipeing and Remote Sensing No. 10, 1976. 2. USSR Author's Certificate for Application No. 271 015/1 8-10, cl. G 03 27/78, 1979 (prototype). J C () 9 / Vpftj