RU2037863C1 - Method of producing color positive image with use of color negative, enlarger and illuminator - Google Patents

Abstract

FIELD: color additive photographic printing. SUBSTANCE: method of producing color positive image comprises steps of forming at least three parallel light beams of blew, green and red colors, direction them onto negative with mutual inclination one relative to another and relative to the negative, projecting onto a photosensitive material or onto a screen. The method may be performed with use of an enlarger, including at least three optical channels, each channel having a light source, an optical system, an additive filter and a reflector, having at least three reflecting members, each is mounted on an optical axis of the respective optical channel in such a way, that their optical axis behind the reflector are mutually parallel and images of the light sources are arranged in a front focal plane of a condenser of the enlarger. That allows to decrease a time period of exposure by 20-40 times and to receive high quality photopositives with any desirable enlargement, including super-high one, with keeping a definition of the image, its color saturation and contrast degree. Spring, had been produced by such method, gives a sensation of volumetric image of objects, being filmed. EFFECT: enhanced quality of prints. 19 cl, 5 dwg

Description

 The invention relates to photographic equipment and can be used for color additive photo printing.

 There is a method of forming a color positive image from a color negative, in which at least three light streams of blue, green and red are formed, then to obtain more uniform illumination of the negative, they are mixed on a diffuse element, the negative is illuminated by the combined light stream and projected onto a photosensitive material [1] The uniformity of illumination in the known method is achieved due to the diffuse scattering process on the diffuse element. However, the presence of a diffuse element causes significant losses in luminous flux and a decrease in the power utilization factor of light sources, which, in turn, leads to a significant increase in exposure time. When illuminated with such a combined luminous flux, a decrease in image sharpness and color distortion on a photosensitive material are observed compared to direct lighting, i.e. undistracted, beams of light.

 A known enlarger for color additive printing, comprising a illuminator in which at least three optical channels are located, each of which contains a white light source and a filter whose transmission spectral range corresponds to blue, or green, or red, and a diffuse reflector, on which flows of all three colors are mixed and the combined light flux is reflected on the condenser, behind which there is a negative holder with a negative, which is projected by the lens onto the exposed color photographic material [1] In this well-known enlarger, uniform illumination of the negative is obtained by diffuse scattering of colored light fluxes on a diffuse element. However, when using a combined stream of scattered light, image sharpening and color rendition on the photosensitive material are reduced compared to direct lighting, i.e. undistracted, beams of light. In addition, the presence of a diffuse element leads to significant losses in luminous flux and a decrease in the power utilization factor of light sources.

A known illuminator that can be installed in an enlarger for color additive printing, including a housing in which at least three optical channels are placed, each of which contains a white light source and a filter whose transmission spectral range corresponds to blue, or green, or red , and a diffuse reflector, on which the flow of all three colors is displaced and reflected in the outlet of the illuminator, which can be combined with the plane of the condenser in the photo magnification body [1]
In this known light source, a uniform combined light flux is obtained due to diffuse scattering by the diffuse element. However, when such a illuminator is used to illuminate the negative during photo printing, the image sharpness decreases and the color rendering is distorted on the photosensitive material as compared with direct, i.e., non-diffused, light beams. In addition, the presence of a diffuse element causes significant losses in luminous flux and a decrease in the power utilization of the light source.

 The purpose of the invention is to reduce the exposure time while obtaining high-quality images with increased sharpness, contrast, color saturation, primarily at high magnifications, which allows to obtain large and ultra-large photo prints that are comparable in quality to reproductions obtained by the printing method.

 The goal is achieved in that in the method of obtaining a color image from a negative, in which at least three beams of blue, green and red colors are formed, they illuminate the negative and project it with a projection system onto a screen or photosensitive material, form parallel light beams passing through negative at an angle to each other and to the plane of the negative. Moreover, all parallel light beams can pass at the same angle to the plane of the negative, and the axis of symmetry of the parallel light beams can be located symmetrically with respect to the optical axis of the projection system.

 In addition, the goal is achieved due to the fact that in the enlarger containing the illuminator containing at least three optical channels, each of which contains a white light source and an additive filter, the transmission spectral range of which corresponds to either blue, or green, or red, and a reflector, and a condenser, a negative holder and a lens sequentially installed behind the illuminator, in each optical channel of the illuminator an optical system is introduced in front of the additive filter, containing at least one memory, and the reflector is made of at least three reflective elements, each of which is installed in the corresponding optical channel, and the light sources are optically coupled to the front focal plane of the condenser, and the optical axes of all optical channels after the reflective elements are parallel to the optical axis of the condenser and are offset relative to her. Such a mutual arrangement of the illuminator and the condenser makes it possible to obtain uniform illumination of the negative without the use of diffuse elements, which, all other things being equal, can reduce the exposure time by 20–40 times.

 For ease of installation and alignment of the optical system and for printing black and white photographs, it is possible to introduce an additional optical channel containing a white light source and an optical system including at least one lens and an additional reflective element. The reflective surface of the reflecting elements can be made flat. In addition, the extensions of the optical axes to the reflective elements can intersect with the optical axis of the condenser at one point and at the same angles. It is possible that the optical axes of the reflective elements are located in the same plane, while if the white light sources are point or linear, they can be optically coupled to the surface of the reflective elements and the front focal plane of the condenser simultaneously, i.e. images of light sources formed by the corresponding optical systems will be located on the surface of the reflective elements.

 In addition, it is possible that the optical axis of the channels are symmetrically relative to the optical axis of the condenser. In addition, the reflector can be made in the form of at least a trihedral regular pyramid, the edges of which are reflective elements.

 The task can be achieved by creating a illuminator containing at least three optical channels, each of which contains a white light source and an additive filter, the spectral transmission range of which corresponds to either blue, or green, or red, and a reflector in each optical whose channel, in front of the additive filter, an optical system is introduced containing at least one lens, and the reflector is made of at least three reflective elements, each of which is installed It is shown in the corresponding optical channel, moreover, the optical axes of all optical channels after the reflective elements are parallel to each other, and the light sources are optically coupled to one plane.

 In addition, it is rational to introduce an additional optical channel containing a white light source and an optical system comprising at least one lens, and an additional reflective element mounted on the optical axis of the additional optical channel is introduced into the reflector, and its optical axis after the reflective element is parallel to the rest of the optical axes, and the light source is optically paired with the same plane as other light sources.

 In this case, the reflective elements can be made flat. It is possible that the extensions of the optical axes to the reflective elements intersect at one point, and the angles between the direction of the optical axis of the channels before and after the reflective elements are equal in all optical channels. It is most convenient if the optical axes to the reflective elements are located in the same plane. Moreover, if the white light sources are made point or linear, then they can be optically coupled simultaneously with both the front focal plane of the condenser and the surface of the reflective elements, i.e., the images of light sources generated by the corresponding optical systems will be located on the surface corresponding reflective elements. In addition, the optical axis of the channels can be located symmetrically, and in this case, the reflector can be made in the form of at least a trihedral regular pyramid, the edges of which are reflective elements.

 In FIG. 1 shows an optical circuit of a illuminator in conjunction with a photographic enlarger condenser; figure 2 optical scheme of the enlarger; figure 3 design of the illuminator; in FIG. 4 design of the enlarger; figure 5 view of the illuminator with an additional optical channel from the side of its output window.

In FIG. 1, a part of the optical scheme of the photo enlarger is conventionally shown, containing two of at least three optical channels of the illuminator 1 and a condenser 2. Each optical channel contains a light source 3 _i (hereinafter, i is the serial number of the optical channel), the optical system 4 _i , an additive filter 5 _i , behind which a reflective element 6 _{i is} mounted on the optical axis.

As follows from the drawing and the laws of reflection, the angle α _i between the optical axis of the channel and the plane of the corresponding reflective element 6 _i is associated with the angle β _i between the optical axis of the pre-reflective element and after it the following ratio: α _i 90 ^about β _i / 2. In order for the optical axis of the channels after the reflective elements to be parallel to the optical axis of the condenser, it is necessary that β _i = γ _i , where γ _{i is the} angle between the optical axis of the channel to the reflective element and the optical axis of the condenser. Thus, the reflective elements 6 _i must be installed at an angle α _i 90 ^about -γ _i / 2. In this case, the image planes of the light sources 3 _i formed by the optical systems 4 _i must be located in one plane that coincides with the front focal plane of the condenser 2.

 In this case, the light flux from each light source, i.e. all three colors should overlap each other at the input of the condenser, so it is necessary that the images of light sources are located as close as possible to the optical axis of the condenser, but not overlap each other. The image of the brightness body should be entirely inscribed in the area of the face of the reflector, not laminating.

 In FIG. Figure 1 shows the general case of the arrangement of the optical axis of the channels to the reflective elements, i.e. they can be located at different angles to the optical axis of the condenser. However, from the point of view of design, the most convenient is the location of the optical axes to the reflective elements in the same plane symmetrically to the optical axis of the condenser. In this case, the extensions of the optical axes to the reflective elements intersect with the optical axis of the condenser at one point.

 In addition, the reflective elements can be made in the form of faces of a multifaceted pyramid, the top of which is located on the optical axis of the condenser.

In FIG. 2 is an optical diagram of the entire enlarger, the illuminator 1 of which contains three optical channels, each of which contains a light source 3 _i , an optical system 4 _i containing lenses 7 _i , 8 _i and additive filters 5 _i respectively of red, blue and green colors, and the reflective elements are made in the form of faces of a regular trihedral pyramid 9. The optical channels are located symmetrically relative to the optical axis of the capacitor 2, and their optical axis to the reflective elements are located in the same plane.

 Behind the condenser 2, containing two lenses 10 and 11, a negative 12, a lens 13, and a photosensitive material 14 are mounted.

In this case, the images of the light sources 3 _i generated by the optical systems 4 _i are located in the front focal plane of the condenser 2, on which the axial points H _{i of} these images and the front focus F _{to the} condenser 2 are indicated.

 In FIG. 3 shows the design of the illuminator.

The proposed illuminator includes a housing 15, in which there are three light sources 3 _i , which can be selected as halogen lamps with a body 16 _i in the form of filaments, designed to create streams of white light. Lamps 3 _{i are} mounted on their own cartridge holders 17 _i mounted in the base 18 of the housing 15. Each of the lamps 3 _{i has} its own optical system 4 _i containing lenses 7 _i , 8 _i and additive filter 5 _i . Thus, each optical system 4 _{i is} designed to focus a beam of white light received from the respective lamps 3 _i and to extract from this white light beam a beam of a specific wavelength, that is, a color beam, namely blue, green and red. Each of the lenses 7 _i , 8 _i and filters 5 _{i are} fixed in partitions 19, 20, which are supported in the base 18 of the housing 15 and in its cover 21, forming autonomous compartments (optical channels).

The illuminator also contains a reflector 9 mounted in the housing 15 on the optical axes of the optical systems 4 _i .

The reflector is made in the form of a trihedral pyramid, the faces 22 of which are reflective elements, the base 23 is facing the cover 21 of the housing 15. The trihedral pyramid is attached to the cover 21 with a screw 24, which also serves as an adjustment element when the reflector is installed at the desired height. Here, the optical axes of all optical systems 4 _i lie in the same plane, and the faces of the pyramid serve as reflective elements.

 In FIG. 4 shows the construction of an enlarger, the illuminator of which has a shaft 25, which in this case is made adjustable in height, for example, sliding or telescopic. The shaft 25 is mounted on a frame 26, inside of which a capacitor 2 is installed, made in the form of two-plano-convex lenses 27, 28 (the frame 26 and the condenser 2 are shown conditionally). The frame 26 by means of the bracket 29 is mounted on a slider 30 mounted by means of a screw 31 with a possibility of movement along the rod 32. A negative holder 33 with a negative 12 is installed behind the condenser 2 in the groove of the frame 26. To the base 34 of the frame 26 are mounted 36 with a possibility of vertical movement along the holder 35 with the object 37. Between the base 34 of the bed 26 and the stove 36 is installed fur 38.

 When sharpening due to the latch 39 (adjusting screw), the negative 12 is installed in the focal plane of the lens 37.

 The enlarger also contains a desktop 40, on the surface of which a photosensitive material is fixed, the image is projected onto the latter. The lens 13 is placed at a predetermined height above the table 40 due to the slider 30 with the screw 31, and also due to the adjusting screw 39 (depending on the projection format and the desired sharpness).

Figure 5 presents a view of the illuminator from the side of its output window. In this case, the reflector 9 is made in the form of a tetrahedral pyramid, the number of lamps here is four. An additional lamp 3 ₄ , identical to other lamps 3 ₁ -3 ₃ , is designed to create a stream of white light and has its own optical system 4 ₄ , which differs from the above in that it does not have a filter and a beam of white light enters the reflector. Obtained in this case, a separate beam of white light is used for ease of installation and adjustment of the entire optical system of the source, as well as for printing black and white photographs.

 When describing the operation of the illuminator 1 and the enlarger, we use the optical circuit shown in figure 2. For a better understanding, consider the work on the example of one optical channel.

When the lamp 3 _{1 is} turned _{on, a} stream of white light enters the optical system 4 ₁ to obtain a converging beam of rays that passes through an additive filter 5 ₁ , for example blue, is reflected from the reflective element of the reflector 9, made in the form of a regular trihedral pyramid, and forms an image of the light source . Moreover, the images of all light sources are located in the same plane, and the axis of the optical channels after the reflective elements are parallel to each other. When such an illuminator is installed in the enlarger, the plane in which the images of the light sources are located is combined with the front focal plane of the condenser, the optical axis of which is parallel to the optical axes of the channels after the reflective elements.

 In this case, light beams of all colors should mutually overlap in the entrance pupil of the condenser, which is necessary for the most uniform illumination of the negative.

 Due to the fact that the images of light sources are located in the front focal plane of the condenser, many parallel colored light beams emerge from it, each of which passes at an angle to the negative plane and to each other. This creates a uniform and very intense illumination of the negative, and the structure of the light source is not reproduced in the plane of the negative. The image of this negative 12 is built by the lens 13 on the photosensitive material 14.

In this case, the structure of the image obtained in the image plane on a photosensitive material, when viewed under a microscope or at very high magnifications, has the form of individual dots of three additional colors located on a white background, which resembles a raster printing system in printing. At the request of the photographer, the 3 _i lamps can be switched on either simultaneously or alternately. To achieve the necessary color balance, each lamp must work strictly dosed time. Thus, at the output of the illuminator, a combined luminous flux is obtained, consisting of direct unscattered beams of blue, green, and red with a uniform distribution of the luminous flux. The proposed illuminator is characterized by increased compactness and simple in the absence of moving parts.

 The combined stream of light consists of direct unscattered beams of pure colors, which makes it possible to use it advantageously in artistic photography, achieving, when using the proposed enlarger, for example, a 10-50-fold increase while improving the sharpness and contrast of photo prints and reducing the exposure time by 20-40 times.

 In this case, optimal results can be obtained with light sources having bodies of brightness of point, as well as linear and flat shapes. Real light sources have finite dimensions along the optical axis, and part of the surface of the brightness body will not be located in the front focal plane of the condenser. However, the proposed design provides high image quality in this case, as well as in the case when due to inaccurate installation or adjustment, only a part of the surface of the brightness body is located in the front focal plane of the condenser.

 In the case of four light sources (Fig. 5), it is possible to preset the sharpness and framing when the white light source is turned on without filters, and also use it for black-and-white printing, which increases the service life of the filters, saves energy and increases convenience during work .

 Thus, as a result of using the proposed method and a photo magnifier that implements it, it is possible to obtain high-quality photo prints with any magnifications, including super-large ones, while maintaining high sharpness of the image, its color saturation and contrast, and, in addition, the photo print gives a sense of the volume of the displayed object.

 In addition, the proposed illuminator can be used both for obtaining color photo prints with universal magnifiers of almost all known systems, in photographic printers, in photocopy machines, and as an original source of combined color light for entertainment events, in film and television shooting.

Claims (19)

 1. A method of obtaining a color positive image from a color negative, in which at least three light beams of blue, green and red colors are formed, illuminate the negative with a projection system and project it onto a photosensitive material or onto a screen, characterized in that parallel beams are formed light and direct them to the negative at an angle to each other and to the plane of the negative.  2. The method according to claim 1, characterized in that parallel colored beams of light are directed at the same angles to the plane of the negative.  3. The method according to PP. 1 and 2, characterized in that the axis of symmetry of the parallel beams are located symmetrically relative to the optical axis of the projection system.  4. An enlarger comprising a illuminator comprising at least three optical channels, each of which contains a white light source and an additive filter, the transmission spectral range of which corresponds to either blue, green, or red, and a reflector, and a condenser installed sequentially behind the illuminator , a negative holder and a lens, characterized in that in each optical channel of the illuminator an optical system is introduced in front of the additive filter containing at least one lens, and the reflector is made at least three reflective elements, each of which is installed in the corresponding optical channel at an angle to its optical axis, the optical axis of all optical channels after the reflective elements are parallel to the optical axis of the condenser, and white light sources are optically coupled to its front focal plane .  5. The enlarger according to claim 4, characterized in that an additional optical channel is introduced comprising a white light source and an optical system including at least one lens, and an additional reflective element mounted on the axis of the additional optical channel is introduced into the reflector, wherein the optical axis the additional channel after the reflective element is parallel to the optical axis of the condenser, and the white light source is optically coupled to its front focal plane.  6. Photographic enlarger 4 and 5, characterized in that the reflective surfaces of the reflective elements are made flat.  7. The enlarger according to claim 6, characterized in that the extensions of the optical axes to the reflective elements intersect with the optical axis of the condenser at one point and at the same angles.  8. The enlarger according to claim 7, characterized in that the optical axis of all the optical channels to the reflective elements are located in the same plane.  9. Photographic enlarger 7 and 8, characterized in that the optical axis of the channels are symmetrically relative to the optical axis of the condenser.  10. The enlarger according to claim 9, characterized in that the reflector is made in the form of at least a trihedral regular pyramid, the faces of which are reflective elements, and the apex is located on the optical axis of the condenser.  11. Photographic enlarger 6 to 10, characterized in that the white light sources are made point or linear and are optically coupled to the planes of the corresponding reflective elements.  12. A illuminator comprising a housing in which at least three optical channels are placed, each of which contains a white light source and an additive filter, the transmission spectral range of which corresponds to either blue, or green, or red, and a reflector, characterized in that in each optical channel, an optical system containing at least one lens is introduced in front of the additive filter, and the reflector is made of at least three reflective elements, each of which is installed in the corresponding optical matic channel at an angle to its optical axis, the optical axes of all optical channels after reflecting elements are parallel to each other, and white light sources optically conjugate with a plane.  13. The illuminator according to claim 12, characterized in that an additional optical channel is introduced comprising a white light source and an optical system including at least one lens, and an additional reflective element mounted on the optical axis of the additional optical channel is introduced into the reflector, wherein the optical axis after the reflective element is parallel to the remaining optical axes, and the white light source is optically coupled to the same plane as other white light sources.  14. The lighter according to paragraphs. 12 and 13, characterized in that the reflective elements are made flat.  15. The illuminator according to claim 14, characterized in that in all optical channels, the angles between the direction of the optical axis, respectively, before and after the reflective element are equal, and the extensions of the optical axes to the reflective elements intersect at one point.  16. The illuminator according to clause 15, wherein the optical axis of all the optical channels to the reflective elements are located in the same plane.  17. The lighter according to paragraphs. 15 and 16, characterized in that the optical axis of the channels are symmetrically relative to the line passing through the intersection point of the extensions of the optical axes to the reflective elements parallel to the optical axis of the channels after the reflective elements.  18. The illuminator according to claim 17, characterized in that the reflector is made in the form of at least a trihedral regular pyramid, the faces of which are reflective elements.  19. The lighter according to paragraphs. 14 to 18, characterized in that the white light sources are made point or linear and are optically coupled to the planes of the corresponding reflective elements.

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