DE10058525A1 - Color image display method has display color for each image point selectively adjusted via associated value held in memory - Google Patents

Abstract

The display method has image data transferred to a control unit (7) for a color image display device (1), which determines the actual colors for the individual image points (2) of the image display in order to reproduce the image. The color for each image point can be adjusted in dependence on an associated value held in a memory (23), e.g. for matching the displayed colors to different environmental conditions. An Independent claim for a color image display device is also included.

Description

State of the art

The invention relates to a method for displaying Color images according to the genus of the main claim. There are different types of display units are known in which by mixing several primary colors a colored picture with a variety of possible colors. Usually red, green and blue are used as primary colors.

Possible ads are e.g. B. cathode ray tube displays, where phosphors are used by an electron beam Lights in the primary colors can be excited. Furthermore are Liquid crystal displays are known in which individual Liquid crystal cells with color filters in the primary colors are provided. A single pixel in one desired color should appear, and part of a colored overall picture, continues with both Liquid crystal displays as well Cathode ray tube displays each from a partial pixel of the primary colors red, green and blue together. The color white is activated by simultaneous activation of the red, the green and blue pixels reached. That through this Mixture generated white is of the color of each Phosphors in the cathode ray tube display or by the color of the color filter and the color of the  Backlighting in the liquid crystal display dependent. Generally, an ad should the color white should be desired, the three sub-pixels red, green and blue controlled equally. By a variation of the ratio of the control of individuals Primary colors to each other can be the color of the display reproduced white tone can be varied. Dependent on all other colors are of the same color as the white can be influenced, even between the primary colors Colours. Are different display devices used next to each other, so you can not carried out comparison of the individual display devices different color impressions arise, which lead to a Can irritate a user. Furthermore, especially depending on a temperature or a Operating time or an age of Liquid crystal display backlight or one Operating time of the cathode ray tube display it to one Change in hues as a result of temperature or age-dependent change of phosphors or color filters come. This can affect the readability of an advertisement deteriorate, or it can especially in Comparison to other components for a user of the Impression that the display device is not works properly. Changes or adjustments in Color representation is only possible by the whole picture is converted or by the color setting for the Control of the primary colors set manually becomes.

Advantages of the invention

The present invention with the features of The main claim has the advantage that one Pixel assigned to a display unit in  Dependency on a stored value is changeable. This enables a color adjustment without the image data to convert itself, but only the color adjustment when displayed in a respective display device. A display device can therefore be surrounding it, too executed in completely different techniques Display devices, e.g. B. a light emitting diode or Incandescent lighting of other units or to one Color of a mounting frame can be adjusted without a additional user intervention is required. Through a simple exchange of values that change the serve the first color, a desired color impression will be realized. In addition, manufacturing tolerances of Display units are balanced in the color rendering. A mixture of individual primary colors is preferably used Representation of the color actually to be represented, so that a value for a color change from partial values for composes every single basic color.

By the measures listed in the subclaims advantageous further developments and improvements of the Main claim specified procedure possible. Especially is advantageous, the values for changing a first Save color non-volatile, so even after a Switching off the device does not recalculate the in the Store stored values is required or that these Values have to be transferred to the memory again.

It is also advantageous to change the value of the first color to be determined by an arithmetic unit since this makes it possible to adjust the displayed color, z. B. aging of the display or the Ambient light, especially when the display is operating in the dark by a color representation adapted to it. In particular, it is advantageous to have a regulation for a  Determination of the values for the change of the first color preferably in a non-volatile compressed form save, as compared to saving a full color table takes up less space becomes. This rule can then be through an interface adapted to the respective application of the display device be fed.

It is also advantageous to store the values in the memory in Dependence on the measurement results of a sensor change, because in this way an adaptation of the color locus to an environmental situation is possible. In particular it is advantageous, depending on one Light source temperature, especially when using a cold cathode fluorescent lamp for backlighting a Liquid crystal display to adjust the color locus because of the Color locus of such a lamp is very different from that Lamp temperature depends. This can make a change the display colors when the Ad lighting can be at least partially compensated.

It is also advantageous depending on the Age of a light source or cathode ray tube to change the color location of the display, as this will make an old Display device have the same color representation can, as it has a newer display device, so that a use of different age display device is not recognizable side by side. This is preferable a mounting date e.g. B. the light source in the Control unit saved.

It is also advantageous that the in the memory is not volatile stored values via a user input are changeable, so that in particular with one Manufacturing process a display device to different  Customer demands can be customized without each appropriate programming is required. Further This enables a user to use a device adapted to a first application and now this device wants to use in an application, e.g. B. in another Motor vehicle, through a corresponding user input Color representation can be easily adjusted. Either Several control instructions are stored internally are or the data for the operation of the display device can be transmitted via an external interface.

It is particularly advantageous to provide a white balance, where the white location, i.e. the representation of the color white is matched by the display, preferably by a Matching for all primary colors. Here is the Viewing various display devices by one User a simple comparison or comparison possible because with the color white all basic colors are controlled. In particular, the use of the invention Process in a liquid crystal display advantageous because here in addition to those used in the liquid crystal display Color filters also the color of the backlighting the color location affected.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the following description. It shows Fig. 1, a display device of the invention in connection with a device whose data is shown in the display unit, Fig. 2 shows a process flow according to the invention, Fig. 3 shows another exemplary embodiment of an inventive display apparatus.

Description of the embodiment

The present invention can be used for a variety of Display devices are used. Below is the present invention using a liquid crystal display in a motor vehicle explained. However, the present Invention also in other vehicles or outside of Vehicles to adapt any display, in particular also used by liquid crystal displays become.

In FIG. 1, a display unit 1 is shown, which is implemented as a liquid crystal display. The display unit 1 has pixels 2 , with a pixel 2 consisting of a first partial pixel 3 , a second partial pixel 4 and a third partial pixel 5 . For reasons of clarity of the drawing, only one pixel 2 is labeled. The first partial pixel 3 has the color red, the second partial pixel 4 has the color green and the third partial pixel 5 has the color blue. The colors of the individual pixels are generated by color filters incorporated in the liquid crystal display. The brightness of the individual pixels is controlled by individually controllable liquid crystal cells, with individual partial pixels being controllable separately. The structure of the liquid crystal cells themselves is not shown in FIG. 1. The display unit 1 is illuminated by a light source 6 which is arranged on the side of the display unit 1 and whose light is coupled into a light guide plate arranged on a side facing away from the user (backlighting) or in a light guide plate arranged on a side facing the front (front lighting). The light guide plate is also not shown in FIG. 1. The display unit 1 can also be designed with direct backlighting (not shown in the drawing), in which light sources are arranged on the display unit 1 designed on the side of the liquid crystal display facing away from a viewer. The display unit 1 is controlled by a control unit 7 . The individual pixels are operated via row and column control devices, also not shown in FIG. 1, the control data of which are transmitted to the display unit 1 by the control unit 7 . The control unit 7 transmits a control signal for the red partial pixels via a first data line 8, a control signal for the green partial pixels via a second data line 9 and a control signal for the blue partial pixels via a third data line 10 . The control unit 7 also has a data interface 11 . The control unit 7 is also connected to a non-volatile memory 14 , in which at least one defined color table (color look up table) is stored. In a preferred embodiment, the non-volatile memory 14 is integrated in the control unit 7 . In a preferred embodiment, control instructions for 256 different colors are stored in the non-volatile memory, according to which a pixel can reproduce a desired color by controlling the respective partial pixels. The non-volatile memory is also used in a preferred exemplary embodiment for the storage of partial images which are requested by the control unit 7 and can be output in the display. The control unit 7 is also connected to an image memory 24 , which is designed as a volatile memory and in which images calculated or determined by the control unit 7 or the electrical device 16 are stored, e.g. B. images that are copied from the non-volatile memory 14 into the image memory. The control unit 7 is also connected via a first interface 15 to an electrical device 16 , from which image data or request data, according to which image data are generated by the control unit 7 , are transmitted to the control unit 7 . The electrical device 16 has a computing unit 17 and a non-volatile memory 18 in which adjustment values for the color adjustment are stored. The computing unit preferably takes on other control tasks and general calculation functions in the electrical device 16 , which are not shown in the drawing. Via a second interface 19 , the electrical device 16 can be connected to other devices, e.g. B. access a bus system. The electrical device 16 can be connected to an operating unit 20 which has operating elements 21 . Furthermore, the electrical device is connected via a data connection 12 to a temperature sensor 13 which is arranged on the light source 6 and with which a temperature of the light source 6 can be measured.

When the display device is initialized, the arithmetic unit 17 copies the color table from the non-volatile memory 14 into the arithmetic unit 17 of the electrical device 16 . The color table is changed on the basis of a regulation that is stored in the non-volatile memory 18 of the electrical device 16 . The regulation specifies which of the preferably 256 colors, which are stored in the color table, are to be changed and in which way. The color values are preferably numbered here. So z. B. be a requirement to assign all color values between the number 100 and the number 150 to a color value whose atomic number is two larger. This means e.g. For example, in the case of image data which assign the color number 110 to a pixel, the color to which the number 112 is assigned in the color table is actually output in the display. The changed color table is transmitted by the computing unit 17 to a volatile memory 23 of the control unit 7 . An image representation is now calculated and / or determined by the computing unit 17 in the electrical device 16 , e.g. B. a street map. The required for the representation of data obtained, the electric device 16 via the second interface 19, or it calculates itself. The electrical device 16 is z. B. as a display device for vehicle data, e.g. B. a vehicle speed, as a navigation device, as a car radio or any other multimedia device in a vehicle. The image determined by the computing unit 17 is transmitted to the control unit 7 , which copies the image data from the non-volatile memory 14 into the image memory 24 . The control unit 7 , which also has a computing device 22 , reads out the image memory 24 at cyclical time intervals, preferably at a frequency that is high enough that the human eye can no longer perceive flickering. Here, the color values of the image data stored in the image memory 24 are changed in accordance with the changed color table in the volatile memory 23 , and the individual colors are displayed in the display unit 1 in accordance with this change. A control signal for the individual primary colors red, green and blue is calculated from the image data in accordance with the changed color. For this purpose, the computing device 22 has register memories which allow the first color of a pixel stored in the image memory 24 to be changed quickly to the changed color.

A control value for the individual primary colors for each pixel is thus determined as a function of a color desired for a single pixel, taking into account the regulation stored in the non-volatile memory 18 and the values for changing the color stored in the volatile memory 23 . Results z. B. from an image signal for a pixel a control of a pixel of 80% of a maximum brightness for the colors red and green and 40% of a maximum brightness for the color blue and is in the non-volatile memory 18 for the color determined thereby z. For example, if the blue component is increased by 5%, the blue component for controlling this pixel is increased to an activation of 45% of a maximum brightness. If the blue component is increased in this way for all colors, the display appears bluish. A correction can, however, also be limited to certain predeterminable colors. B. a warning function can be represented by certain colors all in a warning color, for. B. be changed to a bright red.

A change in color can be given in a regulation for selected colors. For intermediate color values that lie between these selected colors, the correction to be carried out is then interpolated, so that a prescription or a correction value need not be stored in the non-volatile memory 18 for each color that can be represented by the display unit 1 . The non-volatile memory 18 is preferably designed as an EPROM (Electronic Programmable Read Only Memory), that is, as a memory that, for. B. can be overwritten by the computing unit 17 . If a different representation of colors is now desired, new correction values or a new regulation for changing color values can be supplied to the non-volatile memory 18 via the interface 19 of the control unit 7 . Likewise, the correction values stored in the non-volatile memory 18 can be changed when the desired function is appropriately selected by a user by means of the operating elements 21 of the operating unit 20 . Furthermore, various correction values can be stored in the non-volatile memory 18 , which can then be selected accordingly by a user. The corresponding color locations can also be stored differently in the non-volatile memory 18 for different devices that can be connected to the first interface 15 . In addition to the electrical device 16 , further devices can be connected to the control unit 7 , the interfaces of which are not shown in FIG. 1 for reasons of clarity of the drawing. The light source 6 is preferably designed as a cold cathode fluorescent lamp. The emitted color spectrum of these lamps is often heavily dependent on the operating temperature of the lamp. A feedback to the electrical device 16 about the color location of the light with which the display unit 1 is backlit is thus possible via the temperature sensor 13 . The computing unit 17 can be used to select a corresponding memory area from the non-volatile memory 18 , that is to say a corresponding regulation for processing the image signal and for generating the control signal, in which correction values for different color spectra are stored, so that the display unit 1 provides a constant color representation can. Furthermore, it is e.g. B. possible to detect the ambient brightness and to adapt the color location to the ambient brightness, especially to light falling on the display unit 1 . In addition, the seating position of an observer can be detected by a sensor, which can also produce a different color impression depending on the viewing angle of the display unit 1 . Depending on the seating position, the color location can also be compensated for in this case.

A process sequence according to the invention is shown in FIG. 2. Before data is displayed in the display unit 1 , the control unit 7 is initialized in an initialization step 30 by writing values for the color change into the volatile memory 23 of the control unit 7 as described for FIG. 1. The display itself begins with an image signal transmission and image determination step 31 , in which a signal is transmitted from the electrical device 16 to the control unit 7 , with which the output of a specific image is requested. For this purpose, a corresponding image or partial image is copied from the non-volatile memory 14 into the image memory 24 , which is read out by the computing device 22 of the control unit 7 at regular time intervals. In a subsequent conversion step 32 , the image data, e.g. B. so-called bitmap data, corresponding to the values stored in the volatile memory 23 for changing the respective colors changed by the computing device 22 . In a subsequent control step 33 , a control signal for the pixels of the display device is determined on the basis of the changed image data by the computing device 22 . In a subsequent output step 34 , a color image is displayed in the display unit 1 . In a further exemplary embodiment, which is not shown in the drawing, a conversion can also be carried out after the determination of a control signal, a conversion being carried out here for the individual primary colors.

A consideration of the age of the display lighting, z. B. a first date of use of the light source 6 is stored, or an ambient temperature, which is determined by means of the temperature sensor 13 , or the measurement results of other sensors, is preferably carried out in the initialization step 30 of the control unit 7 , which may also during operation at least with respect to a change the color values stored in the volatile memory 23 are repeated.

In FIG. 3, another embodiment of an inventive display apparatus is illustrated for performing the method according to the invention. An image signal is transmitted directly to a control unit 47 , which is connected to the temperature sensor 13 and the control unit 20 . A computing device 46 , an image memory 48 and a non-volatile memory 49 are arranged in the control unit 47 . The computing device 46 writes the image data obtained via an interface 45 into the image memory 48 . A color table with values is stored in the non-volatile memory 49 , on the basis of which the computing device 46 changes the color of the image data stored in the image memory 48 when the image data is output to the display unit 1 .

Claims (13)

1. A method for displaying color images from individual pixels, image data being transmitted to a control unit of a display unit and / or image data being determined by the control unit, colors of the individual pixels to be displayed in the display unit being determined from the image data, characterized in that a first color assigned to a pixel on the basis of the image data is changed as a function of a value stored in a memory and assigned to the first color. 2. The method according to claim 1, characterized in that the value for changing the first color is non-volatile is saved. 3. The method according to any one of the preceding claims, characterized in that the value for the change the first color is determined by a computing unit and that the value for changing the first color is volatile is saved. 4. The method according to claim 3, characterized in that a regulation for changing different first ones Colors is stored non-volatile.   5. The method according to claim 4, characterized in that a rule for changing the first color over an interface can be fed. 6. The method according to any one of the preceding claims, characterized in that the value for the change the first color depending on the measurement result Sensor is changed. 7. The method according to claim 6, characterized in that a temperature of an indicator light via the sensor is determined. 8. The method according to any one of the preceding claims, characterized in that the value for the change the first color depending on an age is selected at least by parts of the display unit. 9. The method according to any one of the preceding claims, characterized in that the value for the change the first color depending on user input is changed. 10. Use of the method according to one of the preceding Claims for white balance of a display unit. 11. Display device with a display unit, one Control unit and a memory for performing the Method according to one of the preceding claims. 12. The display device as claimed in claim 11, characterized in that an interface for transmitting data to the memory ( 14 ) is connected to the control unit ( 7 ) and / or to the memory ( 14 ) and / or to an electrical device ( 16 ) , 13. Display device according to one of claims 11 to 12, characterized in that the display unit ( 1 ) is a liquid crystal display.