DE102008017072A1 - Implementation of color information for the control of a light source - Google Patents

Abstract

The invention relates to a method for converting color information for activating a light source, wherein color information is transferred from a first color space (R1) into a second, larger color space (R2) using a coordinate system (S) which represents colors. According to the invention, two different color locations (f1, f2), which lie in the coordinate system (S) on a straight line (g) running through a central point (z), are displaced relative to the central point (z) nonlinearly along the straight line (g) to transfer the color information. In this manner, a transformation of the color spaces can be achieved while maintaining the color tones. Furthermore, through the nonlinear shift, there is only a relatively small color change in a central whitish area about the central point (z), so that the danger is reduced of obtaining a color location which has a significant color from a color location which is "whitish" originally, that is before the transfer.

Description

The The invention relates to a method for converting color information for driving a light source, wherein a color information under use representing a color Coordinate system transferred from a first color space in a second, larger color space becomes.

If certain color effects or color sequences with a light source, For example, an LED light (LED: light-emitting diode), must be generated as a rule for a corresponding Activation of the light source first the corresponding color information is generated. Usually This is done using a liquid crystal screen (LCD: liquid crystal display) - im Also called "display" for short - performed. in this connection turns the fundamental Problem that generally affects the amount of all colors with Such a display can be generated from the set of all possible Colors of light generated with the relevant light source can be different. In the case of usual LED lights, the colored one Can generate light, It is true here that usually not all the colors associated with the luminaire can be generated can also be generated on the display.

To specify a certain amount of colors, there are different possibilities; For example, the known so-called CIE standard color chart (CIE: Commission Internationale de l'éclairage) can be used for this purpose. This is a two-dimensional coordinate system for representing colors, with the different colors within an approximately horseshoe-shaped area; on the abscissa x-coordinates of color locations are plotted, on the ordinate the corresponding y-coordinates. In 2 is schematically outlined the CIE standard color chart. (Please note that due to the given conditions no color representation is possible, therefore it should be remembered that blue shades are to be found in the lower left area of the "horseshoe", greenish hues in the upper area, red hues in the area of the right corner and there are yellow shades between the green and red areas, and in a central area of the horseshoe there is a whitish area.)

Furthermore, in 2 outlines the three color loci R, G, B of the well-known sRGB color model (sRGB: standard RGB), which is usually used in displays (color locus R in the red area with x = 0.64, y = 0.33, color locus G in green Range with x = 0.30, y = 0.60 and color locus B in the blue range with x = 0.15, y = 0.06).

As is known, by mixing the corresponding three colors R, G, B, all the colors which lie within a triangle whose vertices correspond to the color loci R, G, B can be produced; in 2 this triangle is also drawn.

In the following, the amount of all colors that are within a certain range in the standard color chart or generally in a color chart is called "color space". The color space formed by the three named color locations R, G, B is accordingly designated by "sRGB color space"; in 2 the sRGB color space is designated by the reference symbol R1.

A light source with which light can be generated in different colors usually has a plurality of bulbs, each of which can emit light of a particular color. By appropriately differently weighted control of the lamps can produce light of different colors with such a light source. All colors that can be generated in this way are thus again in the representation of the CIE standard color chart within a polygon whose vertices exactly correspond to the coordinates of the colors in which the individual light sources of the light source can emit light. In 2 is exemplified for such a polygon a triangle E1, E2, E3 located. Accordingly, the amount of colors limited by this triangle will hereinafter be referred to as "light source color space" R2.

you recognizes that in the example shown schematically, the light source color space R2 is bigger than the sRGB color space R1.

to Conversion of color information from the sRGB color space R1 into the Light source color space R2 could provided that the colors of the sRGB color space R1 with their x and y coordinates the standard color chart 1: 1 transferred to the light source color space R2 become. This would have However, that means that the possibilities the light source, light of certain colors, by far not completely be exploited.

Alternatively, the sRGB color space R1 could be transformed into the light source color space R2 such that the vertices R, G, B of the sRGB color space R1 coincide with the vertices E1, E2, E3 of the light source color space R2. This is in 3 indicated by corresponding dotted arrows. However, this would mean that shades move. For example, it can be seen that with such a procedure the color locus G is transferred or transformed into the color locus E2, and therefore a much darker color due to this transformation from a more yellowish green Green emerges.

Of the The invention is based on the object, an alternative method for the implementation of color information for controlling a light source indicated; in particular, it should be the Farbdarstellungsmöglichkeiten the light source as possible can be largely exploited.

These Task is according to the invention with those in the independent ones claims mentioned objects solved. Special embodiments of Invention are in the dependent Claims specified.

According to the invention is method for implementing color information for driving a light source provided with a color information using a color coordinate system transferred from a first color space in a second, larger color space becomes. For transmission the color information becomes two different color locations, in the coordinate system on a through a central point extending straight lines, with respect to the central point in non-linear Way moved along the line.

It thus becomes a nonlinear stretch with respect to the center point carried out.

Thereby, that the color locations are moved along a straight line through a central point runs, let yourself achieve that the hue or hue of a color location at the shift or transformation is not changed. So it will be an implementation of color information allows at the color tones remain. Continue lets in that two lying on such a straight, different Color loci with respect to the central point in a non-linear manner be moved, achieve that colors, originally - ie before the transmission or transformation - appear whitish, by the transmission only relatively little changed become. This leaves reduce the risk of getting out of an originally "whitish" color spot by transferring a color is created, which has a distinct color. To this Way is thus allowing that the impression of the original Color information by the implementation as little alienated or falsified becomes.

Advantageous becomes the color locus that is farther from the central point lies, as the other color place, further shifted along the straight line, as the other color place. This allows the circumstance to be taken into account be that the human eye differences between less saturated Perceives colors more clearly than between more saturated colors.

Advantageous are the color locations with the help of a non-linear mathematical Function, such as an exponential function, a polynomial function or a Stair function, moved along the straight line.

Advantageous several color locations are moved along the line, with a Color place, originally is located on a boundary of the first color space, moved to a color location which lies at the corresponding boundary of the second color space. That way the second color space optimally exploit.

Advantageous the central point is a white point. For example, it can be provided that as a coordinate system a CIE standard color chart is used and as a central point a white point, for example, the point with the coordinates x = 0.3300 and y = 0.3300. If the center point is a white point, the shift occurs or transformation along one from the white point outgoing line, so by shifting the hue not changed becomes.

According to the invention is furthermore a use of a method according to the invention for programming light effects or light sequences of a light source intended. It can be advantageously provided that the transmission of the Color information is performed using a display whose color space with identical to the first color space. In particular, it can be provided be that the display is connected to a PC and the transmission continues to be performed using the PC. Alternatively it can be provided that the display is connected to the light source and the light source Means of implementation of the method. Further advantageous, the light source a color space identical to the second color space.

The Invention will be described below with reference to an embodiment and with reference closer to the drawings explained. Show it:

1 a sketch of an embodiment of a method according to the invention, wherein a color information is transmitted from an sRGB color space into a light source color space using the CIE standard color chart,

2 a sketch of the general relationship of an RGB color space to a light source color space,

3 an explanatory sketch for a possible implementation of color information from a first color space in a second, larger color space.

On the 2 and 3 has already been discussed above.

In 1 is a sketch of an embodiment of a method according to the invention for the implementation of color information for controlling a light source shown. In this case, a color information is transmitted from a first color space into a second, larger color space using a coordinate system representing colors. Thus, an "original color information" is transferred or transformed by the conversion or transformation into a "transmitted color information", the original color information relating to colors from the first color space and the transmitted color information to colors from the second color space.

at The color information may be, in particular, information act to produce color effects or color sequences using the Light source can be used.

at the light source may be a light source comprising several in particular at least three, lighting means, each Light of a different color can produce, with the bulbs independently can be dimmed from each other. By appropriate control can be with such Light source accordingly generate light in different colors.

at The light sources may be, for example, LEDs. at Accordingly, the light source can be, for example, an LED chip act with several corresponding LEDs.

It be explicit mentioned, according to the invention, the light source Also, more than three bulbs may have light in each create a different color. For example, so can a light source with four or five or even be provided more such bulbs.

at representing the colors Coordinate system may be, for example, the standard color chart act according to CIE, 1931. However, it is also possible for this another Coordinate system to use, for example, the standard color chart after CIE, 1964 or an equidistant chromatic chart, such as the CIE 1976 color chart.

at the first color space R1 can be a color space of a color model act that is used in a display. For example, can It is thus an RGB color space, for example the sRGB color space act. It can be provided in particular that the display is used, using a method according to the invention To program lighting effects or sequences of light with the light source should be generated.

at the second, larger color space R2 may be, in particular, the color space of the light source, So the amount of all possible Colors of light that can be generated with the light source.

Of the second color space is, as already mentioned, larger than the first color space. In the coordinate system used is thus the area that is occupied by the first color space, smaller than the area that is occupied by the second color space. It is not mandatory required that in the coordinate system used the limits of the second color space completely outside the boundaries of the first color space. So the two color spaces can quite intersecting Have borderlines.

For transmission The color information according to the invention are two different color locations f1 and f2, in the coordinate system on a through a central point z extending straight lines g, with respect to the central point z shifted in a nonlinear fashion along the line g. "Non-linear" should be in expressing in this context that the degree of displacement not proportional to the distance of the relevant color locus f1, f2 is from the central point z. So it will be with reference to the central point z performed a non-linear stretching. It can in particular be provided that the two color locations f1, f2 on a half-way lying starting from the central point z, where the color locations f1, f2 exclusively be moved along this half-way.

In 1 For example, the two color locations f1 and f2 are each marked with a cross, with the two color locations f1 and f2 lying within the first color space R1, that is to say within the sRGB color space in the example shown. The color location f1 is shifted by the transfer or transformation of the color information into the color location f1 ', the color location f2 in the color location f2'. The shifted or transformed color locations f1 ', f2' lie within the second color space R2. In 2 the transformed color locations f1 ', f2' are each marked with a small circle.

The central point z lies in a central region of the first color space R1. For example, the central point z may be a white point, ie, for example, in the case of the CIE standard color chart shown, around the point with the coordinates x = 0.33 and y = 0.33. However, it is also possible to provide another white point as the central point, for example one of the white points designated in the literature as D50, D55, D65, D75 or D9300. By selecting a particular one of several possible white points as the central point z, special characteristics of an environment to be illuminated with the light source can be taken into account. It can therefore be provided that the central point z is selected as a function of properties, in particular light-color influencing properties of an environment of the light source.

Thereby, that the two color locations f1, f2 lie on the line g, the through the central point runs or from this leaves to achieve that when moving or stretching the color locations f1, f2 into the transformed color loci f1 ', f2' none or at least no significant change in hue occurs. In this way, so a total of a shade-sustaining implementation the color information allows.

In the in 1 As shown, the color locus f1 is farther from the central point z than the color locus f2. It is provided that the color location f1 is moved further along the line g, as the color location f2. In particular, it can be provided that the color location f1, which is farther away from the central point z, is shifted disproportionately far with respect to the original distance to the central point z and compared to the displacement of the closer color location F2.

It Thus, it may be provided that with reference to the central point z a non-linear stretching is performed, the imaging or stretch factor at a color location in an environment of the center point z is smaller than at a color location outside of this environment. hereby is enabled that the entire color space R2, so the entire light source color space can be used. Furthermore can be effected in this way, that near the central point z the transmission or transformation of the color information does not cause that a color place, originally, so before the transfer the color information, in a whitish area in the environment from z lies so far that it is clearly perceptible Color characteristic receives and in this way to a falsification of the impression of the original Color information could contribute.

For example it can be provided that the two color locations f1, f2 with the aid of a non-linear mathematical function, such as a Exponential function, a polynomial function or a staircase function, be moved along the line g.

Especially can be provided that multiple color locations along the line g, where a color location fg, originally at a boundary of the first color space R1 is due to the transmission moved to a color location fg ' which is at the corresponding boundary of the second color space R2 is. With "corresponding" limit of second color space R2 is the boundary of the second color space R2 denotes, as seen from the central point z, in the same Direction lies like the relevant boundary of the first color space R1.

at Use of the exponential function can thus be provided, for example be that the color locus fg, which was originally on the line g the boundary of the first color space R1 is located, so at the intersection the straight line g with the respective boundary line of the color space R1, so far postponed that after transmission as color locus fg 'at the corresponding Border of the light source color space R2 is located. For that color place, originally coincides with the central point z, For example, the shift or stretch factor 1 = exp (0) (ie the coordinate values to be provided) and for the intermediate color loci respectively shift or stretch factors, resulting from a weighting with the exponential function at the both mentioned boundary conditions.

It For example, a function may be provided in which a small environment of the central point z is defined, all Includes color loci, to some extent referred to as "whitish" can be. For the transmission can then be provided that those color locations that are originally within of this environment are transmitted 1: 1 and those color locations that are originally outside the area, be shifted so that the second color space R2 are completely filled can.

For transmission the entire color information can be provided that the above described methods with arbitrary resolution accuracy for all color loci, the original in the first color space R1 is performed. So you can For example, accordingly any number of half-lines provided be that star-shaped from the central point z or from a white point.

In general, the result is that the transformation or stretching is different for each color or hue, because in general two different distances occur for two half-lines or for two different "hues" between the boundary of the first color space and the corresponding boundary of the second color space. It can therefore be provided in particular that the transformation is non-linear and thereby selected for each hue so that just the boundary of the first or inner color space corresponding saturation is mapped to the corresponding boundary of the second and larger color space corresponding saturation ,

As mentioned above, It is not absolutely necessary that the boundaries of the first color space R1 with the boundary lines of the second color space R2 do not overlap. It can therefore also in the above procedure in general for education a half-way point on which the color locations through the transfer closer to the center point z are pushed so that all color locations, the original lie on this half-way, after their transformation within of the second color space R2.

general formulated can therefore be provided that all color locations after their transformation within the second color space R2.

Advantageous can the inventive method So to the programming of light effects or light sequences one Be used light source. As already mentioned above, can be provided that for programming the lighting effects or light sequences a display is used whose color space is identical to the first color space R1. The display can do this be connected to a PC, wherein the transmission of the color information continues to be performed using the PC. Alternatively, it can be provided be that the display is connected to the light source and the light source Means of implementation of the method. Advantageously, the light source thereby a color space identical to the second color space R2.

Claims (9)

Method for converting color information for controlling a light source, color information being transmitted from a first color space (R1) into a second, larger color space (R2) using a coordinate system (S) representing colors, characterized in that two are used to transmit the color information different color locations (f1, f2) lying in the coordinate system (S) on a straight line (g) passing through a central point (z) with respect to the central point (z) are displaced along the straight line (g) in a non-linear manner become. The method of claim 1, wherein said color locus (f1) farther from the central point (z) than the another color locus (f2), moving further along the line (g), as the other color location (f2). A method according to claim 1 or 2, wherein the color loci (f1, f2) with the help of a non-linear mathematical Function, such as an exponential function, a polynomial function or a staircase function, along the line (g) are moved. Method according to one of the preceding claims, wherein several color locations are moved along the line (g) and thereby a color locale (fg) originally is at a boundary of the first color space (R1), to a color location (fg ') is moved, that at the corresponding boundary of the second color space (R2) lies. Method according to one of the preceding claims, wherein the central point (z) is a white point. Use of a method according to one of the preceding claims for programming light effects or light sequences of a light source. Use according to claim 6, wherein the transfer the color information is performed using a display, whose color space is identical to the first color space (R1). Use according to claim 7, wherein the display with connected to a PC and the transfer continues performed using the PC or the display is connected to the light source and the light source Means of implementation of the method. Use according to any one of claims 6 to 8, wherein the light source has a color space identical to the second color space (R2) is.