JP2005354728A - Chrominance signal correction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress variation of the chromaticity point of a monochromatic color interlocked with variation of the gradation level, and to suppress variation of the chromaticity point with the gradation characteristics of an achromatic color. <P>SOLUTION: A chrominance signal correction device is used for an image display device that displays an image by the lights generated from light emitters by irradiating the light emitters with an electron beam. The device comprises a light-emission-characteristics correction unit that performs a correction process to the chrominance signals of multiple colors which respectively correspond to multiple kinds of light emitters that respectively emit different lights, for correcting the emitted-light luminance characteristics of each color; an offset-value determining means that determines an offset value based on the luminance level of at least one chrominance signal selected from the inputted chrominance signals of the multiple colors; and an offset-value adding means that adds the adjusted offset value to at least one remaining chrominance signal. The offset value is the one for the chromaticity correction that suppresses the variation of the chromaticity point of a predetermined color interlocked with the variation of the luminance level of the predetermined color. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a television receiver, which receives a television signal or an image signal from a computer or the like and displays an image using a display such as a plasma display (PDP), an electroluminescence display (ELD), or an electron emission display. The present invention relates to an image display device such as a display device and a color signal correction device used therefor.

  Taking TV signals such as NTSC and HDTV, which are image signals, as an example, this is intended for a receiver using a CRT, and the CRT has a γ characteristic (non-linear characteristic of luminance signal-light emission luminance characteristic). ) Is corrected in advance on the sending side (referred to as γ correction) and output.

  However, a phenomenon may occur in which the light emission amount of the display does not accurately correspond to the luminance level of the image signal.

  As an example, in the case of an electron emission display, in a multi-electron beam source in which cold cathode elements and the like are wired in a simple matrix, the selection time of one pixel is increased due to the adoption of line sequential driving. A time when the (phosphor) is irradiated with the electron beam becomes too long, and the amount of light emitted from the phosphor may show a saturation phenomenon that is not proportional to the electron beam irradiation time. In this specification, this phenomenon is referred to as phosphor saturation.

  The degree of saturation varies depending on the type of phosphor, electron beam density, electron beam irradiation time, and the like.

  If the saturation characteristics vary depending on the phosphor material and the type of color, the color balance of the displayed image, particularly the achromatic (white) chromaticity point, does not become a desired value.

  A technique for solving such a problem is disclosed in Patent Document 1, for example. FIG. 13 shows the saturation characteristics corresponding to the gradations of the RGB phosphors described in Patent Document 1. In FIG. 13, the horizontal axis represents normalized luminance data, and the vertical axis represents normalized luminance.

  Then, the inverse luminance function (correction function) of the upward convex curve shown in FIG. 13 is calculated, and the corrected luminance data is calculated by substituting the input luminance data (also referred to as luminance requirement value or gradation data) into the correction function. Thus, the emission luminance of the phosphor becomes linear with respect to the input luminance data. Then, by having the correction function for each of RGB, the saturation characteristic of each phosphor can be corrected.

In addition to this, white adjustment methods are proposed in Patent Documents 2, 3 and the like.
JP 2000-75833 A JP 63-160492 A JP 2001-119717 A

  However, these conventional techniques have not sufficiently suppressed fluctuations in the chromaticity points of achromatic colors and chromatic colors.

For example, in the method of correcting the output luminance level with respect to the input gradation level of the color signal as in Patent Document 1, it is possible to correct the nonlinearity of the luminance, but still achromatic color in conjunction with the change in the gradation level. The phenomenon that the chromaticity point of fluctuates cannot be suppressed. Specifically, on the CIE xy chromaticity diagram, when the white chromaticity point at each gradation level after correcting the phosphor saturation is expressed, the white chromaticity is linked to the change in the gradation level. The point sometimes fluctuated from point 21 to point 22 like the measurement point shown in FIG.

  As a result of intensive studies by the present inventors, the variation of the chromaticity point according to the change of the gradation level, in particular, the variation of the chromaticity point of the achromatic color is a tristimulus value in the single-color gradation characteristic of the phosphor of each color. It has been found that this is due to the fact that all XYZ have different saturation characteristics.

  In particular, in many of the phosphors used in the display, Z in red and green phosphors exhibits gradation characteristics close to a straight line as compared to X and Y whose saturation characteristics are relatively similar to each other. (See FIG. 15). In FIG. 15, the horizontal axis represents normalized gradation data, and the vertical axis represents the normalized value of tristimulus values.

  Accordingly, when the inverse function of the saturation characteristic of Y is corrected as a correction function, even if the gradation characteristic of Y becomes linear, Z is overcorrected, and the gradation characteristic of Z is a downward convex characteristic. (See FIG. 16). In FIG. 16, the horizontal axis represents normalized gradation data, and the vertical axis represents normalized tristimulus values after correction.

  As can be seen from FIG. 16, due to the relative shortage of the Z component in red and green, the XYZ balance after correction, that is, the difference between the X or Y value and the Z value is the gradation level. Since it fluctuates according to the change, the chromaticity point also fluctuates even for a single color that is a chromatic color. In addition, in the achromatic white, only the Z component is extremely reduced depending on the gradation, and thereby the balance of the XYZ components is lost. Changes, and the chromaticity point of white fluctuates.

  The present invention has been made on the basis of the above-described new knowledge of the present inventor, and its purpose is to suppress the balance fluctuation of the tristimulus values XYZ at each gradation level, and tones due to the saturation characteristics of the illuminant. Providing a color signal correction device and an image display device equipped with the color signal correction device to improve the display image quality by suppressing the fluctuation of the chromaticity point of a single color linked to the change of the level or the fluctuation of the chromaticity point of an achromatic color There is to do.

  In order to achieve the above object, the present invention adopts the following configuration.

  A first aspect of the present invention is a color signal correction device used in an image display device that displays an image by light emission of the light emitter generated by irradiating the light emitter with an electron beam, and a plurality of light sources that emit light of different colors. A light emission characteristic correction unit that performs a correction process for correcting the light emission luminance characteristic of each color on a plurality of color signals corresponding to each of the light emitters, and at least one selected from the input color signals of the plurality of colors Offset value determining means for determining an offset value based on the luminance level of the color signal, and offset value adding means for adding the adjusted offset value to at least one remaining color signal, The offset value is a chromaticity correction offset value for suppressing a change in the chromaticity point of the color in conjunction with a change in the luminance level of the predetermined color. It is a correction device.

The second aspect of the present invention includes a light emission characteristic correction unit that performs a correction process for correcting the light emission luminance characteristic of each color on a plurality of color signals respectively corresponding to a plurality of light emitters that emit light of different colors. An apparatus for correcting color signals, comprising: an offset value determining means for determining an offset value based on a luminance level of at least one color signal selected from input color signals of at least one color; and at least one remaining color An offset value adding means for adding the offset value to the signal, and a prohibiting means for prohibiting the addition of the offset value when it is determined that a color signal indicating a single color is input, The offset value is a chromaticity correction offset value for suppressing a change in the chromaticity point of the color in conjunction with a change in the luminance level of a predetermined color. A.

  According to the present invention, by correcting the color signal of each color so as to keep the balance of the tristimulus values, a change in the chromaticity point of a single color linked to the change in the gradation level, which has been a conventional problem, and Variations in chromaticity points in achromatic gradation characteristics can be suppressed.

  Exemplary embodiments of the present invention will be described in detail below with reference to the drawings.

  1 and 2 are block diagrams of a color signal correction apparatus according to an embodiment of the present invention.

  The color signal correction device 801 performs light emission processing for correcting a light emission luminance characteristic of each color on color signals (Ra, Ga, Ba) of a plurality of colors respectively corresponding to a plurality of light emitters that emit light of different colors. A characteristic correction unit (812) is provided.

Then, the color signal correction device 801 has a chromaticity correction offset value (Rb, Gb) for suppressing a change in the chromaticity point of the color in conjunction with a change in luminance level of a predetermined color such as white. Based on the luminance level of at least one color signal (Ra, Ga) selected from the input color signals of a plurality of colors, and at least one remaining value determination means (711, 712) Offset value adding means (731, 732) for adding the offset values (Rb, Gb) to the color signal (Ba).

  As a display to which the present invention can be applied, a display in which a field emission type or surface conduction type cold cathode element and a phosphor emitting light upon receiving electrons as a light emitter are combined, an organic EL element or an inorganic EL as a light emitter. Examples thereof include a display using an element and a plasma display provided with a phosphor that emits light by receiving ultraviolet rays as a light emitter.

  The light emission characteristic correction unit 812 corrects the saturation of the light emitter, that is, by changing the luminance level of the output color signal with respect to the luminance level of the input color signal according to the luminance level, the input color to the display device A non-linear correction circuit that corrects the emission luminance with respect to the luminance level of the signal to be linear is preferably used.

  The color that can suppress the variation of the chromaticity point is not limited to white as an achromatic color, and may be other colors such as chromatic colors such as green, red, and blue. Further, in FIG. 1, both the red signal and the green signal are used as the color signal that provides the luminance level that is a parameter for determining the offset value, but any one of them may be used.

  For example, when suppressing the variation of the green chromaticity point, the offset value (Gb) to be added to the blue signal (Ba) is determined based on the luminance level of the green signal (Ga). Similarly, when suppressing the fluctuation of the red chromaticity point, the offset value (Rb) to be added to the blue signal (Ba) is determined based on the luminance level of the red signal (Ra). Further, in order to suppress the fluctuation of the blue chromaticity point, the offset value (Gb) to be added to the blue signal (Ba) is determined based on the luminance level of the green signal (Ga) (in this case, 0 level). Good.

When the offset value (first offset value) determined based on the other color signal is added to the blue signal (Ba), X of the tristimulus values is the second strongest after Z. In order to reduce the increment of X, it is also preferable to add a negative offset value as a second offset value to a red signal with a large amount of X. In this way, when the luminance level of the red signal is lowered, it is possible to prevent light colors such as skin color and orange from being bluish. Further, it is more preferable that such a negative offset value is determined based on an offset value added to the blue signal.

  Thus, by adding the second offset value determined based on the first offset value by the second offset value adding means to the color signal to which the first offset value is not added, the color of another color is obtained. It is possible to suppress the fluctuation of the degree point.

The offset value adding means used in the present invention is an offset value determined based on a luminance level of one or a plurality of color signals selected from the color signals of the plurality of colors input to the light emission characteristic correction unit. Is added to at least one remaining color signal input to the light emission characteristic correction unit. Alternatively, the offset value adding means uses the offset value determined based on the luminance level of one or more color signals selected from the color signals of the plurality of colors output from the light emission characteristic correction unit, as the light emission characteristics. You may add to the at least 1 remaining color signal output from the correction | amendment part.

  The offset value used in the present invention is preferably a value that increases or decreases nonlinearly with an increase in the gradation level of the color signal.

  It is also preferable to provide an offset value adjusting means such as a multiplier and adjust the offset value in accordance with the balance of the luminance level between the color signals of a plurality of colors. This is effective in suppressing variations in chromaticity points with changes in gradation levels in light colors such as orange, pink, and skin.

  In addition, if you do not want to change the color reproduction range, a judgment means for judging the input of a color signal indicating a single color as a plurality of color signals is provided by a comparator, logic gate, etc. It is also preferable to provide a prohibiting means for prohibiting the addition of the offset value by using a logic gate or the like.

  As the color to which the offset value is added, in the above description, attention is paid to Z among the three stimulus values. However, depending on the type of the light emitter, X and Y may be different from other stimulus value components. Therefore, in that case, it is also possible to change to add an offset value to the red or green color signal.

  Hereinafter, a configuration using a cold cathode device, in particular, a surface conduction electron-emitting device and a phosphor as a display will be described as an example.

(First embodiment)
In the first embodiment, an offset value is selected according to each of the R and G image data so as to keep the balance of the tristimulus values XYZ from the value of the input image data composed of the R and G color signals. The chromaticity point correction unit that adds the offset value to the image data composed of the B color signal, and the image data output from the chromaticity point correction unit respectively correspond to the emission luminance saturation characteristics of each phosphor. A light emission characteristic correction unit that performs saturation correction makes a balance of monochromatic tristimulus values XYZ constant regardless of gradation, and performs correction to suppress fluctuations in chromaticity points of suitable colors, particularly achromatic colors.

In a display device having a multi-electron source in which a plurality of cold cathode elements, in the present embodiment, a plurality of surface conduction electron-emitting devices, are arranged at intersections on a simple matrix by a plurality of scanning wirings and modulation wirings, By incorporating this color signal correction device into an image display device that displays a TV signal on a display panel having a phosphor that emits light upon receiving the electron beam irradiation, an image display device that performs suitable image display can be configured. .

  Hereinafter, the color signal correction apparatus and the hardware configuration of the image display apparatus equipped with the color signal correction apparatus, which are features of the present application, will be described in order.

(Explanation of functions of the entire system and each part)
An overview of a display panel of an image display apparatus according to an embodiment of the present invention, electrical connection having a simple matrix structure, and characteristics of a surface conduction electron-emitting device are described in JP-A-2000-75833. Then, explanation is omitted. In the image display device of the present embodiment, image display is performed by line sequential driving and pulse width modulation means.

  Next, the hardware configuration is shown in FIG. FIG. 3 is a block diagram showing an outline of the circuit configuration.

  Dx1 to DxM and Dx1 ′ to DxM ′ are voltage supply terminals of the scanning wiring of the display panel 1, Dy1 to DyN are voltage supply terminals of the modulation wiring of the display panel 1, and Hv applies an acceleration voltage between the face plate and the rear plate. A high-voltage power supply terminal, Va is a high-voltage power supply, 2 and 2 'are scanning circuits, 3 is a synchronization signal separation circuit, 4 is a timing generation circuit, 7 is a conversion circuit for converting a YPbPr signal into an RGB signal, and 17 An inverse γ processing unit provided as necessary, 10 is a color signal correction device of the present invention, 5 is a shift register for one line of image data, 6 is a latch circuit for one line of image data, and 8 is a modulation wiring of a display panel. Pulse width modulation means for outputting a modulation signal.

  In FIG. 3, R, G, and B are RGB parallel input image data, Ra, Ga, and Ba are RGB parallel image data that has been subjected to inverse γ conversion processing described later, and Rc, Gc, and Bc are color correction signal devices 10. The RGB parallel image data corrected to suppress the variation of the chromaticity point and to correct the phosphor saturation, Data is a data array conversion unit 9 that converts the data array in accordance with the pixel array of the display panel 1 The image data is subjected to parallel / serial conversion by.

  First, the input image signal is separated into synchronization signals Vsync and Hsync by the synchronization separation circuit 3 shown in FIG. The synchronously separated image signal YPbPr is supplied to the RGB conversion means. In addition to the conversion circuit for converting the luminance / color difference signal YPbPr to the primary color signal RGB, a low-pass filter (not shown), an A / D converter, and the like are provided in the RGB conversion means 7, and the YPbPr signal is converted into a digital RGB signal. And is supplied to the inverse γ processing unit 17.

  The timing generation circuit 4 in FIG. 3 is a circuit that generates timing signals corresponding to various video formats and generates operation timing signals for the respective units. The timing signal generated by the timing generation circuit 4 includes Tsft for controlling the operation timing of the shift register 5, a control signal Dataload for latching data from the shift register to the latch circuit 6, and a pulse width modulation start signal for the modulation means 8. Pwmstart, clock Pwmclk for pulse width modulation, Tscan for controlling the operation of the scanning circuit 2, and the like.

  The scanning circuits 2 and 2 'in FIG. 3 are circuits that output a selection potential Vs or a non-selection potential Vns to the connection terminals Dx1 to DxM in order to sequentially scan the display panel row by row in one horizontal scanning period. .

The scanning circuits 2 and 2 'are circuits that perform scanning by sequentially switching the scanning wiring selected every horizontal period in synchronization with the timing signal Tscan from the timing generation circuit 4.

  Note that Tscan is a timing signal group generated from a vertical synchronization signal, a horizontal synchronization signal, and the like.

  Next, the inverse γ processing unit 17 illustrated in FIG. 3 will be described.

  The CRT has a light emission characteristic (hereinafter referred to as an inverse γ characteristic) of approximately 2.2 to the input. The input image signal from the TV broadcast wave takes into account such characteristics of the CRT and is generally converted to have a γ characteristic of 0.45th power so as to have a linear light emission characteristic when displayed on the CRT. Has been.

  On the other hand, the display panel 1 of the image display device according to the embodiment of the present invention has a light emission characteristic that is substantially linear with respect to the application time, as in the case where modulation is performed according to the application time of the drive voltage. The γ processing unit 17 multiplies the input image signal from the TV broadcast wave by 2.2 and converts it into a linear image signal. Such a conversion is called an inverse γ conversion.

(Color signal correction device)
FIG. 2 is a block diagram of the color signal correction apparatus. In FIG. 2, 811 is a chromaticity point correction unit, and 812 is a light emission characteristic correction unit.

  As described above, the chromaticity point correction unit 811 adds an offset value for performing chromaticity point correction to the image data Ra, Ga, and Ba, and uses the resulting image data Rw, Gw, and Bw as light emission characteristics. The data is output to the correction unit 812.

  The light emission characteristic correction unit 812 performs phosphor saturation correction that changes the output luminance level with respect to the input gradation level of the image data Rw, Gw, and Bw and corrects the nonlinearity of the luminance. In this way, image data Rc, Gc, and Bc that have been corrected for suitable colors, particularly white balance fluctuations, are generated.

(Chromaticity point correction unit)
FIG. 1 shows the configuration of the chromaticity point correction unit.

  Reference numeral 711 denotes an R chromaticity correction table, and reference numeral 712 denotes a G chromaticity correction table. Offset values Rb and Gb to be added to the blue image data Ba are output from the R chromaticity correction table 711 and the G chromaticity correction table 712, and are added by adders 731 and 732, respectively. Then, the blue image data Ba is output from the chromaticity point correction unit as image data Bw to which the offset value is added, and is input to the light emission characteristic correction unit 812.

  The delay circuits 721 and 722 are provided for adjusting the output timing by preventing the preceding of the data to which the offset value is not added for the time required for adding the offset value to the blue image data Ba, and for adjusting the output timing. It can be configured using a network.

  The R chromaticity correction table 711 outputs data Rb serving as an offset value to be added to the blue image data Ba based on the red image data Ra. The R chromaticity correction table 711 stores values that increase nonlinearly and then decrease as the gradation level increases, as shown in FIG. That is, the R chromaticity correction table 711 is a non-linear correction table with respect to the gradation direction.

The G chromaticity correction table 712 outputs data Gb serving as an offset value to be added to the blue image data Ba based on the green image data Ga. In the G chromaticity correction table 712, as shown in FIG. 4B, a value that increases non-linearly and decreases with respect to an increase in gradation level is stored. That is, the G chromaticity correction table 712 is a non-linear correction table with respect to the gradation direction.

  4A and 4B show the offset value to be added to the input image data on the horizontal axis and the blue image data on the vertical axis. An example of input / output is 8-bit processing.

  Since the offset values in FIGS. 4A and 4B have the same offset value at several adjacent gradation levels, the number of offset values is suppressed.

  The offset value shown in FIG. 4 is calculated as follows. FIG. 5A shows the gradation characteristics of Z among the tristimulus values XYZ of the red phosphor after luminance saturation correction. A straight line is a line connecting from the highest gradation level to the lowest gradation level, and a downwardly convex curve indicates a measured value. Then, the difference between the straight line and the measured value is obtained, and the gradation value corresponding to the gradation value of the Z value of the blue phosphor is calculated for each gradation level. Create a table of values.

  FIG. 5B shows the gradation characteristics of the stimulus value Z of the green phosphor. For the offset value of the green phosphor, the difference between the straight line and the measured value is obtained in the same way, and the gradation level indicates how many levels of the Z value of the blue phosphor correspond to the difference value. A table of offset values that are non-linear with respect to the gradation direction is created.

The phosphor used in this embodiment is a color cathode-ray tube fluorescence that is currently in practical use, and is known as a so-called P-22 phosphor. That is, copper-activated zinc sulfide phosphor (ZnS: Cu) as a green-emitting phosphor, europium-activated yttrium oxysulfide phosphor (Y ₂ O ₂ S: Eu) as a red-emitting phosphor, and silver as a blue-emitting phosphor An activated zinc sulfide phosphor (ZnS: Ag) is used. In this phosphor, when the blue phosphor is caused to emit light, the Z component is extremely larger than the X and Y components at any gradation. FIG. 6 shows component values of blue tristimulus values that are emission colors in a certain gradation. From FIG. 6, it can be seen that in the blue phosphor, the component value of Z is extremely larger than X and Y. Therefore, the shortage of the Z component can be compensated by correcting the color signal so that the blue phosphor emits extra light.

(Light emission characteristic correction part)
A block diagram of the light emission characteristic correction unit is shown in FIG. The light emission characteristic correction unit 812 includes an R light emission characteristic correction table memory 981, a G light emission characteristic correction table memory 982, and a B light emission characteristic correction table memory 983.

  The R light emission characteristic correction table memory 981 stores a table for outputting corrected image data Rc when image data Rw is input as shown in FIG. FIG. 8A shows the characteristics of the inverse function of the function of the saturation characteristic of the phosphor, and the gradation of the luminance of the red phosphor having the saturation characteristic by the correction table having the characteristic of the inverse function. The characteristic becomes a linear gradation characteristic.

  Similarly, the G light emission characteristic correction table memory 982 stores a table for outputting corrected image data Gc when image data Gw is input as shown in FIG. 8B. FIG. 8B shows the characteristic of the inverse function of the function of the saturation characteristic of the phosphor, and the gradation of the luminance of the green phosphor having the saturation characteristic by the correction table having the characteristic of the inverse function. The characteristic becomes a linear gradation characteristic.

Similarly, the B emission characteristic correction table memory 983 stores a table for outputting the corrected image data Bc when the image data Bw is input as shown in FIG. 8C. FIG. 8C shows the characteristic of the inverse function of the function of the saturation characteristic of the phosphor, and the gradation of the luminance of the blue phosphor having the saturation characteristic by the correction table having the characteristic of the inverse function. The characteristic becomes a linear gradation characteristic. Although the tables in FIGS. 8A to 8C are not the same and are different from each other, they are corrected so that the gradation characteristics of the light emitter having the saturation characteristics become linear gradation characteristics. Circuit.

  In this way, from the red and green image data, an offset value to be added to the blue image data for suppressing the variation of the chromaticity point is obtained, and by adding the offset value to the blue image data, the monochrome gradation is obtained. The balance of the tristimulus values XYZ with respect to the direction is made constant to suppress the change in chromaticity, and the change in the chromaticity point with respect to the gradation direction of the achromatic color can be suppressed, and suitable image data (color signal) is created. be able to.

  Note that the light emission characteristics of the phosphor vary depending on the type of phosphor, the electron beam density, the electron beam irradiation time, the acceleration voltage of the face plate and the rear plate, and the like. Therefore, the chromaticity of the color signal correction device 801 of the present embodiment. The contents described in the various correction tables used in the point correction unit 811 and the light emission characteristic correction unit 812 are not limited to these.

  Then, the output image data Rc, Gc, Bc corrected to suppress the variation of the chromaticity point is output from the color signal correction device 10 to the data array conversion unit 9 in FIG.

  3 has a function of rearranging Rc, Gc, and Bc, which are RGB parallel image signals, in accordance with the pixel array of the display panel, and the RGB parallel image signal is an RGB parallel image signal. It is output to the shift register 5 as serial image data SData. Although not described in detail, it operates based on a timing control signal from the timing generation circuit 4.

  Image data Data, which is output from the data array conversion unit 9 in FIG. 3, is serial / parallel converted by the shift register 5 from a serial data format to parallel image data ID1 to IDN for each modulation wiring. Is output. In the latch circuit, the data from the shift register is latched by the timing signal Dataload immediately before one horizontal period is started. The output of the latch circuit 6 is supplied to the modulation means 8 as parallel image data D1 to DN.

  As shown in FIG. 9A, the modulation means is a pulse width modulation circuit (PWM circuit) including a PWM counter and a comparator and a switch (FET in the figure) for each modulation wiring.

  The relationship between the image data D1 to DN and the output pulse width of the modulation means is a linear relationship as shown in FIG.

  FIG. 9C shows three examples of output waveforms of the modulation means.

  In the figure, the upper waveform is the waveform when the input data to the modulation means is 0, the middle waveform is the waveform when the input data to the modulation means is 128, and the lower waveform is the input to the modulation means. This is a waveform when the data is 255.

  In the present embodiment, the number of bits of the input data D1 to DN to the modulation means is 8 bits. Further, if the output voltage value and output current value of the modulation means are set so that the output luminance level of the light emitter is linear with respect to the input data, the modulation method is not limited to pulse width modulation, Voltage amplitude modulation or current amplitude modulation may be used.

  With such a configuration, when a color signal correction apparatus is mounted and an image is displayed, the balance of tristimulus values can be maintained in the monochrome and achromatic gradation characteristics, which has been a problem in the past. As a result, the variation of the chromaticity point could be suppressed. In addition, since the blue phosphor has a small Y value among the tristimulus values of the color, it was possible to obtain good characteristics with respect to the luminance characteristics. As a natural image, a good image could be obtained.

  In addition, depending on the phosphor, by adding the offset value, another stimulus value of the tristimulus value XYZ may increase, so the red image data instead of the blue image data to be added, Another adjustment offset value (second offset value) to be subtracted may be added according to the first offset value Rb and / or Gb to be added.

(Second Embodiment)
In the first embodiment, when single-color image data is input to the color signal correction device, for example, even if the values of the other color image data excluding the green image data are 0, the value of the green image data is changed. Accordingly, the offset amount is added to the blue image data, output, and the image is displayed. In this case, the color reproduction range may slightly change.

  Therefore, in the second embodiment, in order to prevent deterioration of the monochrome color reproduction range, when monochrome image data is input, an offset value for chromaticity point correction is not added, and other images are not added. When data is input to the color signal correction device, an offset value is selected according to the R and G image data so that the balance of the tristimulus values XYZ is kept constant from the R and G image data values. A chromaticity point correction unit that adds the offset value to the B image data, and a light emission characteristic correction that performs saturation correction corresponding to the saturation characteristic of each phosphor on the image data output from the chromaticity point correction unit A signal processing circuit, that is, a color signal correction device that performs correction for suppressing fluctuations in chromaticity points of a suitable color, particularly an achromatic color, by making the balance of the tristimulus values XYZ of a single color constant regardless of gradation. Constitute.

  The chromaticity point correction unit of the color signal correction apparatus according to the second embodiment will be described with reference to FIG. FIG. 10A shows the configuration of the chromaticity point correction unit 815.

  911 is an R chromaticity correction table, and 912 is a G chromaticity correction table. Offset data Rb and Gb to be added to the blue image data Ba are output from the R chromaticity correction table 911 and the G chromaticity correction table 912 and added by adders 931 and 932, respectively. The blue image data Ba is output from the chromaticity point correction unit 815 as the image data Bw to which the offset value is added, and is input to the light emission characteristic correction unit 812 as shown in FIG.

  The delay circuits 921 and 922 delay data output for the time required for adding the offset value to the blue image data Ra, and can be configured by flip-flops or the like.

  The R chromaticity correction table 911 is configured as shown in FIG. The R chromaticity correction table 911 includes a RED chromaticity correction table memory 951, a comparator 961 (a) 961 (b), a NAND circuit 962, and an AND circuit 963. The RED chromaticity correction table memory 951 outputs data Rb of offset value to be added to the blue image data Ba based on the red image data Ra.

The RED chromaticity correction table memory 951 stores a table shown in FIG. 4A similar to that of the first embodiment. The offset value Rb is nonlinear with respect to the size of red image data.
Will change.

  In the case of the image data of only red single color, nothing is added to the blue image data Ba. Therefore, when the image data Ga and Ba other than red is 0, the comparators 961 (a) and 961 (B) outputs the H level, so that the output of the NAND circuit 962 becomes the L level. As a result, since L is input to the AND circuit 968, when the image data of the image data Ga and Ba other than red is 0, a value of 0 is input to the RED chromaticity correction table memory and the offset is offset. The value data Rb is 0.

  Similar to the R chromaticity correction table 911, the G chromaticity correction table 912 is configured as shown in FIG. The G chromaticity correction table 912 includes a GREEN chromaticity correction table memory 952, comparators 966 (a) and 966 (b), a NAND circuit 967, and an AND circuit 968. The GREEN chromaticity correction table memory 951 outputs data Gb serving as an offset value to be added to the blue image data Ba based on the green image data Ga. A table shown in FIG. 4B is stored in the GREEN chromaticity correction table memory 952, and the offset value Gb changes depending on the size of the green image data Ga.

  Further, in the case of image data of only a single green color, nothing is added to the blue image data Ba. Therefore, if the image data of the image data Ra and Ba other than green is 0, the comparators 966 (a), 966 (B) outputs the H level, and therefore the output of the NAND circuit 967 becomes the L level. As a result, since L is input to the AND circuit 968, when the image data Ra, Ba other than green is 0, a value of 0 is input to the GREEN chromaticity correction table memory and the offset is offset. The value data Rb is 0.

  Thus, when single-color image data is input, the determination means including the comparator and the NAND circuit determines that the image data is monochrome, and the result is determined by the prohibition means including the AND circuit. The address input of the offset value to the memory is stopped and the addition of the offset value to the image data is prohibited. When other image data is input, the offset value of the blue phosphor is obtained from the image data of the red and green phosphors, and added to the blue image data. Correct the light emission characteristics (saturation characteristics).

  In this way, the fluctuation of the chromaticity point of the single color is suppressed, the deterioration of the color reproduction range is prevented, and the balance of the tristimulus values for each gradation level of the achromatic color becomes almost constant, so that the fluctuation of the chromaticity point is changed. Can be suppressed.

  As in the first embodiment, the above-described color signal correction device is mounted on an image display device and an image is displayed. As a result, there has been no problem in the related art without reducing the monochrome color reproduction range. In the gradation characteristics of chromatic colors, the balance of tristimulus values can be maintained, and fluctuations in chromaticity points can be suppressed. In addition, good luminance characteristics were obtained. As a natural image, a good image could be obtained.

  Further, in the present embodiment, in order to prevent the color reproduction range from being narrowed by adding an offset, a description has been given of a configuration in which the offset amount is set to 0 when monochrome image data is input. However, if a single color is slightly mixed with other colors, the hue may change abruptly due to the addition of the offset compared to the case of a single color. Therefore, the offset value is further multiplied by a gain due to the balance of the RGB image data. Thus, a sudden change in hue may be prevented.

(Third embodiment)
FIG. 11 shows configurations of an R chromaticity correction table and a G chromaticity correction table that prevent a sudden change in hue. 11A and 11B, balance adjustment memories 955 and 956 are
GainR and gainG, which are gains according to the balance of the RGB image data, are output respectively, and multipliers 935 and 936 multiply the respective offset values by the gains, and the multiplied values are used for the respective chromaticities. The offset value for point correction is output from the R chromaticity correction table 915 and the G chromaticity correction table 916.

  The balance adjustment memory 955 in FIG. 11 outputs gainR = 1 when the ratio of RGB data is 1: 1: 1. Further, when the ratio of RGB is a single color of 1: 0: 0, gainR = 0 is output. When the RGB ratio is 2: 1: 1, gainR = 0.5 is output. In this way, gain values of 0 to 1 are stored in the balance adjustment memories 955 and 956 according to the RGB balance. By configuring the R chromaticity correction table and the G chromaticity correction table as described above, the color reproduction range is not narrowed, a sudden hue change is prevented, and the chromaticity point variation is suppressed. be able to. Also in this form, the balance adjustment memory determines whether or not the image data is data indicating a single color, and determines the gain to be given to the multiplier as the prohibit means, thereby prohibiting the addition of the offset value for the single color. doing.

(Fourth embodiment)
In the fourth embodiment, the R and G values after saturation correction are maintained downstream of the light emission characteristic correction unit that performs saturation correction according to the saturation characteristic of each phosphor so that the balance of the tristimulus values XYZ is kept constant. A chromaticity point correction unit is provided that selects an offset value according to the value of the corrected image data and adds the offset value to the corrected image data after the saturation correction of B. As a result, the balance of the tristimulus values XYZ of the color is made constant regardless of the gradation, and correction is performed to suppress variation in chromaticity of a suitable color, particularly an achromatic color.

  Hereinafter, the color signal correction apparatus according to this embodiment will be described.

(Color signal correction device)
FIG. 12 is a block diagram of the color signal correction apparatus according to this embodiment. The image data Ra, Ga, Ba are input to the light emission characteristic correction unit 812, perform saturation correction according to the saturation characteristic of each phosphor, output corrected image data Rf, Gf, Bf, and to the chromaticity point correction unit 813. Transferred. The chromaticity point correction unit 813 selects an offset value from the values of Rf and Gf so as to keep the balance of the tristimulus values XYZ constant, and adds the offset value to Bf, so that the tristimulus value XYZ of the color is obtained. A color signal correction apparatus is configured that keeps the balance constant regardless of the gradation and suppresses variation in the chromaticity of the achromatic color.

  The light emission characteristic correction unit 812 has the same configuration as that described in the first embodiment (see FIG. 7). The configuration of the light emission characteristic correction table is the same as that of the first embodiment (see FIG. 8).

  The chromaticity point correction unit 813 has the same configuration as that described in the first embodiment (see FIG. 1). The creation of the offset value table is the same as in the first embodiment.

  As in the first embodiment, the color signal correction device 802 is mounted on an image display device and an image is displayed. In the conventional monochromatic and achromatic gradation characteristics, The balance of tristimulus values can be maintained, and the variation in chromaticity point can be suppressed. In addition, good luminance characteristics were obtained. As a natural image, a good image could be obtained.

  Also in this embodiment, the configurations described in the second and third embodiments can be applied.

Also in the present embodiment, the chromaticity point correction table and the light emission characteristic correction table used in the color signal correction apparatus with the configuration using the cold cathode element have been created and described. However, this embodiment is used in the color signal correction apparatus. The chromaticity point correction table and the light emission characteristic correction table measure their characteristics according to a display such as ELD, PDP, etc., and the values of each table of the chromaticity point correction table and the light emission characteristic correction table may be created. .

  As described above, the color signal correction method according to each embodiment of the present invention can be realized as a functional block by a semiconductor integrated circuit, and can be integrated together with other functional blocks. In this case, the color signal correction method of the present invention can be used in electronic data format as a design asset (IP core) described in HDL and logically synthesizable. The color signal correction method of the present invention may be realized by software that can be executed by a microprocessor.

It is a figure which shows the structure of the chromaticity point correction | amendment part in 1st Embodiment. 1 is a block diagram of a color signal correction apparatus according to a first embodiment. 1 is a block diagram illustrating a schematic configuration of an image display device according to a first embodiment including a color signal correction device. FIG. It is a figure which shows the chromaticity point correction table of the chromaticity point correction | amendment part in 1st Embodiment. It is a graph which shows the gradation characteristic of Z after saturation correction | amendment of red and green fluorescent substance. It is a figure which shows the comparison of the tristimulus value in a blue fluorescent substance. It is a figure which shows the structure of the light emission characteristic correction | amendment part. It is a figure which shows the light emission characteristic correction table in a light emission characteristic correction | amendment part. It is a figure explaining the structure and operation | movement of the modulation | alteration means of an image display apparatus. It is a figure which shows the structure of the chromaticity point correction | amendment part in 2nd Embodiment. It is a figure which shows the structure of the chromaticity point correction | amendment part which prevents that the color reproduction range becomes narrow in 3rd Embodiment, and suppresses the rapid change of a hue. It is a figure which shows the block diagram of the color signal correction apparatus in 4th Embodiment. It is a graph which shows the conventional light emission luminance characteristic. It is a figure which shows the chromaticity point change of the gradation characteristic of an achromatic color after saturation correction | amendment of fluorescent substance. It is a graph which shows the gradation characteristic of the tristimulus value XYZ of red and green fluorescent substance. It is a graph which shows the gradation characteristic of the tristimulus value XYZ after the saturation correction | amendment of red and a green fluorescent substance.

Claims (3)

A color signal correction device used in an image display device for displaying an image by light emission of the light emitter generated by irradiating the light emitter with an electron beam,
A light emission characteristic correction unit that performs a correction process for correcting the light emission luminance characteristic of each color on a plurality of color signals respectively corresponding to a plurality of light emitters that emit light of different colors;
Offset value determining means for determining an offset value based on a luminance level of at least one color signal selected from among the input color signals of a plurality of colors;
Offset value adding means for adding the adjusted offset value to at least one remaining color signal;
Have
The offset value is an offset value for chromaticity correction for suppressing variation in the chromaticity point of the color in conjunction with a change in the luminance level of the predetermined color.
A color signal correction apparatus characterized by the above. The offset value adding means includes
Based on the luminance level of one or a plurality of color signals selected from the color signals of the plurality of colors output from the light emission characteristic correction unit, an offset value determined,
Add to at least one remaining color signal output from the light emission characteristic correction unit, or
The offset value determined based on the luminance level of one or more color signals selected from the color signals of the plurality of colors input to the light emission characteristic correction unit is input to the light emission characteristic correction unit. Append to at least one remaining color signal
The color signal correction apparatus according to claim 1. A color signal correction apparatus including a light emission characteristic correction unit that performs correction processing for correcting light emission luminance characteristics of each color on a plurality of color signals respectively corresponding to a plurality of light emitters that emit light of different colors,
Offset value determining means for determining an offset value based on the luminance level of at least one color signal selected from among the input color signals of a plurality of colors;
Offset value adding means for adding the offset value to at least one remaining color signal;
A prohibiting means for prohibiting addition of the offset value when it is determined that a color signal indicating a single color is input;
Have
The offset value is an offset value for chromaticity correction for suppressing a change in the chromaticity point of the color in conjunction with a change in luminance level of a predetermined color.
A color signal correction apparatus characterized by the above.

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