RU2023278C1 - Process for manufacturing color-correcting compensating optical patterns - Google Patents

Abstract

FIELD: photoprocessing. SUBSTANCE: image pattern is transferred onto photographic color film by exposure of it through optical zonal filters. The resulting image pattern is developed with subsequent color-separated exposure of the image pattern onto black- and white film through optical band-pass filters. EFFECT: improved resolution power. 8 dwg

Description

 The invention relates to the printing processes of the printing industry and can be used to obtain color-separated color-corrected photo images of a colored object.

 There is a known method of manufacturing color-separated color-corrected photoforms, which consists in photographing a colored object on a color photo layer corresponding to a photographic process with the exposure of the exposed photo layer, manufacturing a “gray mask” from the obtained color transparency by copying it onto a black and white photo layer through the appropriate color-separating filters and photo-processing of the exposed black and white photographic layer, color separation photographing on reproduction This camera has a color transparency, combined with a "gray mask" and installed in a slide box of a reproduction camera through a light filter [1].

 The disadvantage of this method is the increased duration of the process, due to the need to manufacture a "gray mask".

 The closest technical solution to the claimed invention is a method of manufacturing color-separated color-corrected photoforms, consisting in photographing a colored object on a color photograph, color photographic printing with the exposure of the exposed photographic layer, manufacturing from the resulting color transparencies a single color mask by contact copying on a color photograph and color photographic printing Exposed photographic layer, color separation photographing at reproduction ohm camera with a color transparency, combined with a single color mask and installed on a black-and-white photo layer through a corresponding color-separating filter in a slide box of a reproduction camera [2].

 The disadvantage of this method is the need to use for the manufacture of a single color mask of expensive color photo layers ("Multimask", "Trimask") purchased for currency funds. Another technological disadvantage of the known method is the need for a long and complex process of color photographic printing processing at a printing company in the manufacture of a single color mask and additional costs for reagents used in the preparation of solutions for color photographic printing processing.

 The purpose of the invention is to simplify and reduce the duration of the process.

 This goal is solved in that in a method for manufacturing color-separated color-corrected photoforms, including exposing an image of an object to colored material, its manifestation, color-division exposure of the obtained image through zonal filters to black and white photographic material and its manifestation, according to the invention, the image of an object is exposed to color photographic material through specified zone filters.

 The essence of the proposed method is as follows.

 To make a color-separated color-corrected negative of yellow paint, a colored object is photographed on a color photo layer through a blue color-separating filter. After color photographic printing processing with the exposure of the exposed photo layer, a yellow color transparency is obtained. This transparencies is installed in a slider of a reproducing camera and color-separable through a blue filter and a black-and-white photo layer are produced, and as a result, a color-separated negative of yellow paint is obtained without color-separation distortions. This effect is achieved due to the fact that on the yellow transparency the areas corresponding to cyan and magenta colors are transparent and when color-separating this transparency through a blue filter, the areas corresponding to cyan and magenta colors of a colored object will transmit a significantly larger light flux to the photo layer, than the corresponding sections of the usual color (multicolor) transparencies having cyan and magenta colors.

 In the manufacture of the color-separated color-corrected negative of magenta paint, a colored object is photographed on a color photograph through a green filter. After color processing with circulation, a magenta transparency is obtained in which the areas corresponding to the yellow and blue inks will be transparent. This transparency is installed in a slide attachment of a reproducing camera and exposed through a green filter to a black-and-white photo layer and after appropriate processing of the exposed photo layer, a color-separated negative of magenta paint is obtained without color separation distortions. This is achieved due to the fact that on the magenta transparencies the areas corresponding to blue and yellow inks will be transparent and when color-separating this transparency through a green filter, these areas will transmit a much larger light flux to the photo layer than similar sections of the color (multi-color) transparency, having blue and yellow colors.

 The production of color-separated color-corrected negative of blue paint is carried out similarly.

 Figure 1-4 shows a diagram of the manufacture of color-separated photoforms according to the prototype method; figure 5-8 is a diagram of the manufacture of color-separated photoforms according to the proposed method.

 An example implementation of the method.

 A colored object (museum picture) is subjected to photographing with a small-format camera, for example, Zenit-TTL on a color film, for example, Orvochrome. Photographing is carried out sequentially through red, green and blue filters on different parts of the photo layer, i.e. when exposed through each filter, they use their own film frame. At the same time, the spectral characteristics and the multiples of the filters used in photographing a colored object are the same as the filters of the corresponding color used in color separation. After exposure, color photographic printing is performed on the exposed frames of a color film with standard color processing modes with appeal for Orvochrome IT-18 film. As a result of color processing, a yellow film is obtained on a film exposed through a blue filter, a magenta film on a film captured through a green filter, and a blue transparency film on a film exposed through a red filter. It is known that a color film has three working layers: the upper emulsion layer is non-sensitized and a yellow dye is formed in it after exposure and color development with inversion, a purple dye is formed in the second emulsion layer (orthochromatic), and is formed in the third emulsion layer (panchromatic) dye of blue color. Between the upper and second emulsion layers there is a yellow filter layer, the role of which is to delay blue radiation so that they do not affect the second and third emulsion layers.

 When a colored object is exposed to an Orvochrome color film through a blue filter, blue radiation acts on the photo layer and causes a reaction only of the upper (non-sensitized) emulsion layer, and blue radiation does not affect the second and third emulsion layers, since it is retained by the yellow filter layer. As a result of the color development in the upper layer, a positive image of the yellow portion of the colored object is obtained, and the sections of the photo layer corresponding to the blue and magenta sections of the colored object will be transparent (see Fig. 5, a). When a color object is exposed to the IT-18 Orvochrome color film through a green filter, green radiation acts on the photo layer. The upper non-sensitized emulsion layer does not respond to green radiation and the radiation passed through the yellow filter layer acts on the second emulsion layer, and the third emulsion layer does not have sensitivity in the green zone and therefore does not respond to green radiation. As a result of the color manifestation with circulation in the second layer, a positive image of the magenta portion of the color object is formed, and the portions of the color object of cyan and yellow on the magenta transparency are transparent (see Fig. 5, b).

 When photographing a colored object through a red filter, red radiation acts on the photo layer. The upper and second emulsion layers do not respond to red radiation. The third emulsion layer reacts to these radiations. As a result of the color manifestation with circulation in this layer, a positive image of the blue portion of the colored object is formed, and the portions of the colored object of purple and yellow on the blue transparency are transparent (see Fig. 5, c).

 After receiving yellow, purple and blue transparencies of a color object, color separation is carried out. Color separation is as follows. A yellow transparency is installed in a slide box of a reproducing camera, for example, RGD-40, and color transmission exposure to a black and white photo layer, for example, FT-22, is performed in transmitted light through a blue color-separating filter. After photographic printing processing of the exposed photo layer, a color-separated negative of yellow paint is obtained, in which the places corresponding to the areas of the colored object of blue and purple (undetectable paints) have densities equal to the density of the white area of the colored object. This effect is achieved due to the fact that on the yellow transparency these sections are transparent (see Fig. 5, a) and therefore they transmit light flux of the same power as the yellow transparency portion corresponding to the white color of the colored object.

 In contrast to the claimed technical solution, the prototype method does not allow to obtain maximum densities in cyan and magenta in the indicated areas of the color-separated negative (see FIG. 2), since the color (multicolor) transparencies used as the original in the prototype method the places corresponding to the cyan and magenta sections of a colored object have cyan and magenta colors, respectively (see Fig. 1), and when color-separating through a blue filter, they will delay part of the luminous flux, since cyan d, and magenta dyes do not completely miss the blue region of the spectrum. As a result of these areas of the black and white photolayer FT-22 is affected by a smaller luminous flux than in the case of using the proposed method, and this leads to lower optical densities for undetectable paints, which, in turn, leads to the need for color correction , which consists in adding the missing densities at the places of the color-separated negative, corresponding to the blue and purple sections of the colored object.

 The modes of color-separation photographing through a blue filter and the post-processing modes of the FT-22 standard photo layer. The color-separated negatives of magenta (see Fig. 5, b and 7) and cyan (see Fig. 5, c and 8) paints are obtained in a similar way.

 The studies performed yielded the following results.

The optical density of color-separated photoforms obtained by the claimed method:
negative blue paint - D ^G = 0.3, D ^P = 2.05, D ^W = 2.10, D ^B = 2.25;
the negative of purple paint - D ^G = 2.03, D ^P = 0.33, D ^W = 2.15, D ^B = 2.23;
negative yellow paint - D ^G = 2.08, D ^P = 2.10, D ^F = 0.38, D ^B = 2.31, where D ^G , D ^P , D ^F , D ^B - optical density corresponding to the index areas of color separated negatives.

 Thus, the proposed technical solution allows to obtain color-separated negatives without color-separation flaws (optical densities for undetectable paints have values equal to the optical density from the white area) and thereby eliminates the need for additional color correction, which reduces the duration of the production of color-separated color-corrected photoforms and simplifies the process .

Claims (1)

 METHOD FOR PRODUCING BETWEEN DIVISIONED FIXED CORRECTED PHOTOFORMS, including exposure of the image of an object to colored material, its manifestation, color-separated exposure of the obtained image through zonal filters to black and white photographic material and its manifestation, characterized in that the image of the object is exposed to color photographic material through said zonal optical filters.

Images