DE3346712C2 - - Google Patents

Description

The invention relates to a method and a front Direction for color synthesis through optical mixing of several Colors and variation in relative intensity at least one of the colors for the purpose of producing a variety of hues distributed over the spectral range.

Under the term "optical mixture" such are not understood physical color mixtures in which trans Parent filters in the beam paths of light sources arranges and the colored light rays by overlay to be brought into interaction with each other. Here can use several filters in the same beam path are connected in series (so-called subtractive  Color mixing), or also through individual filters light rays passing through are directed to at least one partially projected area (so-called additive color mixing). Details of these colors Teaching is the subject of physics textbooks, so that there is no need to go into this further. To "Optical mixing" also includes combined mixing procedure, d. H. subtractive and additive color mixtures can successively on sections of the beam path or also in parts of the cross section of the Beam path take place side by side, then continue is discussed in more detail below.

With the previous color theory there are always three reasons colors used and optionally interacting with each other brought. Here the basic colors become regular Blue, yellow and red used. (Book by Gerritsen "Color", 1975, Otto Maier Verlag Ravensburg). The technical approach However, the application of the three-color theory is complex and requires three separate control systems including the local distribution of the color components their relative intensity (color saturation). This also applies to optical systems (e.g. color TV) as for printing processes, with printing processes in generally also used the color black to counter the so-called graying effect Act.  

Attempts have also already been made to use two beam paths or two different filters, of which only one is a color filter, the color characteristic to project projected images in one Beam path are arranged. By means of the second A colored environment is then projected, a so-called "anti-slide positive", whereby the subjective color perception is changed (DE-OS 16 22 975). Apart from the fact that this involves processes in the human eye or brain play a fundamental role yourself with such a procedure and a corresponding one Device also not essential parts of the paint play spectrum.

The invention is therefore based on the object Processes described above for color synthesis to significantly reduce the effort and still a Variety of colors distributed over the spectral range to produce tones. This should be based on subjective influences like environment and at the same time projected contrast or Complementary colors can be dispensed with.

The task is solved at the beginning described method according to the invention the characterizing part of claim 1 removable measures.  

By the claim 1 removable information which find their support in the diagrams of FIGS. 1 and 2, the dyes are defined with very specific spectral characteristics, either in dissolved form or in the form of ultrafine pigments which Doomed things no appreciable light diffusion, can be applied to a filter carrier in a transparent binder. It is also possible to accommodate such dyes in a homogeneous or quasi-homogeneous distribution in a filter carrier, as is the case with plastic films or glasses colored in the mass.

Examples for the purpose mentioned are: "red violet" A red violet from the group of quinachridone dyes; Hostasol-Red 5B, a fluorescent dye from Höchst AG with the designation 19809 EFBK 305; "Green": Chromium oxide hydrate - Specifically the chromium oxide hydrate, also known as chromium oxide green, is defined by the DIN 6164 standard and has the chemical formula Cr ₂ 0 (OH) ₄ .

It was surprisingly found that one only with the specified colors the whole Spectrum can cover if you look at the colors subtractively and / or additively mixes optically. For example, the Colors red violet, blue, blue violet to green and Yellow-green creates, while additively the colors White, yellow, cyan and magenta can be created.

If you use colors that are noticeably outside the specified spectral characteristic, the effect according to the invention no longer occurs, for example an attempt at a subtractive color mixture using a red-violet filter according to the invention with a green film which does not meet the spectral specification shows only a dirty one Brown, while the use of a filter with the green also according to the invention subtractively leads to a bright blue. On the other hand, a subtractive color mixture of a green filter that corresponds to the spectral specification (curves G 2 a-G 2 c in Fig. 2) and from other television stereo glasses comes in combination with its partner film (red) black, ie absolute impermeability, which is only what Corresponds to the purposes of stereo glasses.

The colors produced according to the invention by color filters are suitable to build up images within a limited Image field and that by locally different Mixing several colors and local variation of the relative intensity or saturation of at least one of the two colors.

This can be particularly advantageous in this way be that one light beam through two  Filters with the colors "red violet" and "green" which filters are at least in parts of the Image field overlap, and that one from the filters emerging colored light rays on a mean seed projection surface with additive color mixing catches.

This "one after the other" can be done both by series connection two filters in the same place (so-called subtractive Color mixing), as well as one after the other, by crossing the light beam by transverse deflection a corresponding filter combination leads, namely at such a rate that human Eye the reunited light impulses as additive Perceives color mixing. Here, the Exploited effect that the projection is more colored Light rays on immediately adjacent surfaces for the human eye represents an additive color mixture, if only the individual color dots are sufficiently close together are different and in relation to the viewing distance are small enough. This effect takes place, for example a widespread use in the picture tubes of color televisions widespread application.

It is particularly useful if you are in the image field in regular distribution and in the same direction arranges a large number of identical filter groups, and these filter groups with the light beam in faster Episode scans.  

The field of view becomes extremely large Number of filter groups under very small dimensions divides so that a picture structure with sufficient detail sharpness is possible. The scanning is done with a periodically deflected light beam, whereby the deflection frequency should be at least 25 Hz to get a flicker-free picture. As still based on the detailed description will be explained in more detail, is the path of the light beam relative to the local one different filter characteristics decisive for the resulting color impression including color inks sity, contrast and brightness.

It is particularly advantageous if you have the light beam over the joints immediately adjacent Filters or filter groups can oscillate and the Hue of the light emerging from the filter groups due to different relative dwell times of the light beam in the individual filters or filters groups influenced.

Another way to influence the color tone results when the beam of light emerging from the filter groups Change in beam cross section in relation to the filter dimensions are changed across the beam. The beam cross section can be relatively simply by the focus state of the Influence the light beam or through masks or screens.  

The invention also relates to a device for Implementation of the above described Process in connection with a light source for the emission of a bundled beam of light and the use of a color filter according to the invention. Such a device is according to the other Er Finding characterized in that the color filter either as a complementary step filter or as complementary gradient filters are formed. The The expression "complementary" means that complement the two filters so that their common envelope represents a cuboid.

A screen can be constructed in such a way that perform a variety of such filter groups shaped and behind in a row a projection surface is attached.

Further advantageous refinements of the counterpart of the invention status result from the other subclaims.

The method and the device according to the invention are suitable for a variety of color processes such as wise: image carrier method, image recording method, Image transmission, image radio, image reception procedures, including duplication procedures Copying process, projection process, image conversion process as well as for electronic and electromechanical paint analysis.

Claims (14)

1. A method for color synthesis by optical mixing of several colors and variation of the relative intensity of at least one of the colors for the purpose of generating a variety of hues distributed over the spectral range, characterized in that only two types of color filters are used, one of which ("Red violet") in the spectral range between approximately 300 and 580 nm has an intensity or transmission maximum between 370 and 460 nm and a minimum between 540 and 580 nm, from which minimum the transmission curve initially rises steeply up to approximately 620 nm a value of the order of magnitude of the maximum and continuously less steeply rising from here into the infrared range above approximately 780 nm, and of which the other ("green") in the spectral range between approximately 300 and 660 nm a transmission maximum between 520 and 560 nm and has a minimum between 640 and 670 nm, from which minimum the transmission curve starts e substantially continuously increases to a transmission value which is approximately in the range of the maximum at 750 to 770 nm, and that the desired color is generated by subtractive or additive or subtractive and additive mixing. 2. The method according to claim 1, for image construction within of a limited image field, characterized by locally mixed mixture of several colors and local variation in relative intensity ("Saturation") at least one of the two colors.   3. The method according to claim 2, characterized in that one beam of light goes through one after the other two filters with the colors "red violet" and "green" guides which filters are at least in part areas of the image field overlap, and that one the colored ones emerging from the filters Rays of light on a common projection area under additive color mixing. 4. The method according to claim 3, characterized in that one in the image field in a regular distribution and a multitude in the same direction arranges the same filter groups and these filters group with the light beam in quick succession gropes. 5. The method according to claim 4, characterized in that the light beam directly over the joints bar of neighboring filters or filter groups oscillate leaves and the color of the filter groups entering light beam by different relative Dwell times of the light beam in the individual Filters or filter groups are affected. 6. The method according to claim 5, characterized in that you can choose the hue from the filter groups entering light beam by changing the beam cross-section in relation to the filter dimensions influenced across the light beam.   7. Device for performing the method according to claims 1 or 2, characterized by

• a) two light sources (1, 2) for transmission according an optically broadband light beam spot (6, 7), wherein in the vicinity of a light source (1) a first green filter (G ₁₎ and in the vicinity of the second light source (2 ) a first red-violet filter (R ₁ ) is arranged and the colored beams are aligned with an at least partially common surface ( 8 ),
• b) two limited openings ( 10 , 11 ) arranged in this common area ( 8 ) in close proximity to one another, in each of which a second green filter (G ₂ ) and a second red violet filter (R ₂ ) is arranged, the second green filter (G ₂ ) on the side of the light source ( 1 ) with the first green filter (G ₁ ) and the second red violet filter (R ₂ ) on the side of the light source ( 2 ) with the first red violet filter (R ₁ ) is arranged,
• c) the two beams ( 6 , 7 ) overlap in the area of the second red violet filter (R ₂ ) over the entire area and in the area of the second green filter (G ₂ ) on about half the side facing the second red violet filter (R ₂ ) and through
• d) a projection surface ( 13 ) arranged approximately parallel to the common surface ( 8 ) at a distance "d", this distance "d" being chosen so that the colored light rays emerging from the second filters (G ₂ , R ₂ ) partially over cut.

8. The device according to claim 7, characterized in that that the optical densities of the first to second green filter at least like 2: 1 and the optical densities of the first to the second red violet filters behave at most like 1: 6. 9. Apparatus for performing the method according to claim 1 for generating a mixed light from the colors "green" and "red violet" for use as a correction device in the color projection, characterized by one each in a common holder ( 14 ) arranged side by side green filter (G ) and red-violet filters (R), which can be moved gradually by means of the holder according to the desired color components in mixed light through the beam path ( 15 ) of a light source. 10. An apparatus for performing the method according to claim 1 or 2 in connection with a light source for emitting an optically broadband bundled light beam and the use of color filters, characterized in that the color filters are designed as complementary step filters ( 16, 17 ) ( Fig. 5). 11. The device for performing the method according to claim 1 or 2 in connection with a light source for emitting an optically broadband bundled light beam and the use of color filters, characterized in that the color filter as a complementary gradient filter ( 19, 20/23, 24/26 , 27 ) are formed ( Fig. 6, 7, 8). 12. The apparatus according to claim 10, characterized in that the color filters ( 16, 17 ) are L-shaped and are complementary such that the common envelope surface is a cuboid. 13. The apparatus according to claim 11, characterized in that the color filters ( 19, 20 ) are wedge-shaped and are complementary such that the common envelope surface is a cuboid. 14. Device according to one of claims 12 or 13, characterized in that a plurality of such filter groups are formed in a strip shape and are arranged in a row arrangement ( 30, 31 ) behind a projection surface ( 13 ).