1. Field
The present invention relates to a display apparatus that displays a color image by controlling the number of emissions or the intensity thereof in accordance with a plurality of primary color video signals input to it, and more particularly to a technique for correcting white balance in a plasma display apparatus that displays a color image by controlling the number of emissions of phosphors of three primary colors, red, green, and blue.
2. Description of the Related Art
Recently, research and development of various types of display apparatus has been proceeding; among them, the plasma display panel (PDP) has been attracting attention as a large screen flat display apparatus capable of crisply displaying characters, images, etc.
The plasma display panel achieves a color display by exciting phosphors of three primary colors, red, green, and blue and, in order to limit power consumption, for example, it is practiced to control the number of emissions (the number of sustain emissions) in accordance with image display ratio (Average Picture Level—APL). However, the luminance ratio among the respective color phosphors varies with the number of emissions; therefore, even when white balance is adjusted, for example, at a specified number of emissions, if the number of emissions changes, the white balance is shifted.
This white balance shift problem occurs due to changes in the number of emissions or the intensity of emission, not only in plasma display panels but also in various other display apparatuses such as display apparatuses using EL elements (electroluminescent elements), FEDs (field emission displays), LED (light emitting diode) displays, and CRTs (cathode ray tubes). Therefore, in a display apparatus that displays a color image by controlling the number of emissions or the intensity thereof in accordance with a plurality of primary color video signals input to it, it is necessary to maintain correct white balance regardless of the number of emissions or the intensity of emission.
Namely, phosphors of the three primary colors, red, green, and blue saturate in luminance as the number of emissions increases. This is because the persistence characteristics of the red, green, and blue phosphors, in other words, the energy conversion efficiency of the phosphors for excitation by ultraviolet radiation, decreases as the number of emissions increases. If white balance is adjusted at a specific point (A) where the number of emissions is large, the white balance value at that time is determined based on the luminance ratio among red, green, and blue at the specific point. On the other hand, when displaying an image in accordance with high APL video signals, the number of emissions is reduced in order to hold the power consumption within a predetermined value.
Accordingly, at another point (B) where the number of emissions is small, the energy conversion efficiency of the phosphors for excitation by ultraviolet radiation increases. If the rate of decrease of the energy conversion efficiency increases in the order of green, red, and blue, then the luminance increases relative to that at the specific point, in the order of green, red, and blue. That is, there is a difference in white balance between the specific point (A) and another point (B) because the luminance ratio among red, green, and blue at the other point (B) differs from the value used for adjustment at the specific point (A).
Conversely, when displaying an image in accordance with video signals whose APL is lower than that when the white balance was adjusted, the number of emissions may be increased, resulting in a further decrease in the energy conversion efficiency, and causing a difference in white balance because the luminance ratio among red, green, and blue changes, as in the case where the number of emissions is decreased.
The prior art and the problem associated with the prior art will be described in detail later with reference to accompanying drawings.
Though an exemplary embodiment of the present invention can be applied not only to plasma display apparatuses but also to various other display apparatuses such as display apparatuses using EL elements, FEDs, and CRTs, the following description will be given by dealing primarily with a plasma display apparatus as an example of a display apparatus that uses phosphors of three primary colors, red, green, and blue, whose persistence characteristics differ from one another.
An object of the present invention is to provide a white balance correction circuit and correction method, for a display apparatus, capable of maintaining correct white balance regardless of the number of emissions or the intensity of emission.
According to an exemplary embodiment of the present invention, there is provided a display apparatus for displaying a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, comprising a detection portion detecting the number of emissions or the intensity; and a white balance correction portion correcting white balance by adjusting the amplitudes of the primary color video signals in accordance with the detected number of emissions or the detected intensity.
The detection portion may detect the number of emissions or the intensity from a display ratio of an image produced by the primary color video signals. The display apparatus may further comprise a control portion controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the display ratio of the image. The white balance correction portion may comprise a computing unit and a plurality of multipliers wherein the computing unit may compute amplitude coefficients for the primary color video signals in accordance with the display ratio of the image, and the multipliers may multiply the primary color video signals respectively by the computed amplitude coefficients.
The white balance correction portion may comprise a storage unit and a plurality of multipliers wherein the storage unit may output amplitude coefficients for the primary color video signals in accordance with the display ratio of the image, and the multipliers may multiply the primary color video signals respectively by the amplitude coefficients output from the storage unit. The white balance correction portion may comprise a storage unit wherein the storage unit may output amplitude-adjusted primary color video signals in accordance with the primary color video signals and the display ratio of the image.
The detection portion may detect the number of emissions or the intensity from a display current that flows when displaying an image in accordance with the primary color video signals. The display apparatus may further comprise a control portion controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the image display current. The white balance correction portion may comprise a computing unit and a plurality of multipliers wherein the computing unit may compute amplitude coefficients for the primary color video signals in accordance with the image display current, and the multipliers may multiply the primary color video signals respectively by the computed amplitude coefficients.
The white balance correction portion may comprise a storage unit and a plurality of multipliers wherein the storage unit may output amplitude coefficients for the primary color video signals in accordance with the image display current, and the multipliers may multiply the primary color video signals respectively by the amplitude coefficients output from the storage unit. The white balance correction portion may comprise a storage unit wherein the storage unit may output amplitude-adjusted primary color video signals in accordance with the primary color video signals and the image display current. The detection portion may detect the number of emissions or the intensity from an external applied luminance-adjusting input.
The display apparatus may further comprise a control portion controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the externally applied luminance-adjusting input. The white balance correction portion may comprise a computing unit and a plurality of multipliers wherein the computing unit may compute amplitude coefficients for the primary color video signals in accordance with the externally applied luminance-adjusting input, and the multipliers may multiply the primary color video signals respectively by the computed amplitude coefficients. The white balance correction portion may comprise a storage unit and a plurality of multipliers wherein the storage unit may output amplitude coefficients for the primary color video signals in accordance with the externally applied luminance-adjusting input, and the multipliers may multiply the primary color video signals respectively by the amplitude coefficients output from the storage unit.
The white balance correction portion may comprise a storage unit wherein the storage unit may output amplitude-adjusted primary color video signals in accordance with the primary color video signals and the externally applied luminance-adjusting input. Emissions due to the primary color video signals may be produced from phosphors of three primary colors, red, green, and blue. The display apparatus may be a plasma display apparatus.
According to an exemplary embodiment of the present invention, there is also provided a display apparatus for displaying a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, wherein output gray levels of images represented by the primary color video signals are adjusted in accordance with input gray levels of the images represented by the primary color video signals, thereby correcting white balance which varies with the number of emissions for, or the intensities of, the primary color video signals.
The display apparatus may further comprise a first detection portion detecting the input gray levels of the images represented by the primary color video signals; and a correction portion correcting the white balance by adjusting the output gray levels of the primary color video signals in accordance with the detected input gray levels. The white balance correction portion may comprise a computing unit and a plurality of correction units wherein the computing unit may compute gray level correction coefficients in accordance with the detected input gray levels, and the correction units may apply corrections to the input gray levels by using the computed correction coefficients.
The white balance correction portion may comprise a storage unit and a plurality of correction units wherein the storage unit may output gray level correction coefficients in accordance with the detected input gray levels, and the correction units may apply corrections to the input gray levels by using the computed correction coefficients. The display apparatus may further comprise a second detection portion detecting a display ratio or display current of an image produced by the primary color video signals; and a control portion controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the detected display ratio or the detected display current.
Further, according to an exemplary embodiment of the present invention, there is provided a white balance correction circuit for use in a display apparatus which displays a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, and which includes a detection portion detecting the number of emissions or the intensity, wherein the white balance correction circuit corrects white balance by adjusting the amplitudes of the primary color video signals in accordance with the detected number of emissions or the detected intensity.
The white balance correction circuit may further comprise a computing unit computing amplitude coefficients for the primary color video signals in accordance with the number of emissions or the intensity; and a plurality of multipliers multiplying the primary color video signals respectively by the computed amplitude coefficients wherein the white balance, which varies with the number of emissions for, or the intensities of, the primary color video signals, may be corrected by adjusting the amplitudes of the primary color video signals in accordance with the controlled number of emissions or the controlled intensity. The white balance correction circuit may further comprise a storage unit storing amplitude coefficients for the primary color video signals, and outputting the amplitude coefficients in accordance with the number of emissions or the intensity; and a plurality of multipliers multiplying the primary color video signals respectively by the output amplitude coefficients wherein the white balance, which varies with the number of emissions for, or the intensities of, the primary color video signals, may be corrected by adjusting the amplitudes of the primary color video signals in accordance with the controlled number of emissions or the controlled intensity.
The white balance correction circuit may further comprise a computing unit computing amplitude coefficients for the primary color video signals in accordance with the number of emissions or the intensity; and wherein the white balance, which varies with the number of emissions for, or the intensities of, the primary color video signals, may be corrected by adjusting the amplitudes of the primary color video signals in accordance with the controlled number of emissions or the controlled intensity. The white balance correction circuit may further comprise a storage unit storing amplitude-adjusted primary color video signals, and outputting the amplitude coefficients in accordance with the primary color video signals and the number of emissions or the intensity; and wherein the white balance, which varies with the number of emissions for, or the intensities of, the primary color video signals, may be corrected by adjusting the amplitudes of the primary color video signals in accordance with the controlled number of emissions or the controlled intensity.
The detection portion may detect the number of emissions or the intensity from a display ratio of an image produced by the primary color video signals. The detection portion may detect the number of emissions or the intensity from a display current that flows when displaying an image in accordance with the primary color video signals. The detection portion may detect the number of emissions or the intensity from an externally applied luminance-adjusting input.
In addition, according to an exemplary embodiment of the present invention, there is provided a white balance correction circuit for use in a display apparatus which displays a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, and which includes a detection portion detecting the number of emissions or the intensity, wherein output gray levels of images represented by the primary color video signals are adjusted in accordance with input gray levels of the images represented by the primary color video signals, thereby correcting white balance which varies with the number of emissions for, or the intensities of, the primary color video signals.
The white balance correction circuit may further comprise a first detection portion detecting the input gray levels of the images represented by the primary color video signals; and a correction portion correcting the white balance by adjusting the output gray levels of the primary color video signals in accordance with the detected input gray levels. The white balance correction circuit may further comprise a computing unit computing gray level correction coefficients in accordance with the detected input gray levels; and a plurality of correcting units for applying corrections to the input gray levels by using the computed correction coefficients. The white balance correction circuit may further comprising a storage unit outputting gray level correction coefficients in accordance with the detected input gray levels; and a plurality of correcting units for applying corrections to the input gray levels by using the output correction coefficients.
The white balance correction circuit may further comprise a second detection portion detecting a display ratio or display current of an image produced by the primary color video signals; and a control portion controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the detected display ratio or the detected display current.
According to an exemplary embodiment of the present invention, there is provided a white balance correction method for a display apparatus which displays a color image by controlling luminance in accordance with primary color video signals input thereto, wherein an amplitude ratio between the primary color video signals is set in accordance with the luminances of the primary color video signals, thereby suppressing variation of white balance with the luminances.
Further, according to an exemplary embodiment of the present invention, there is provided a white balance correction method for a display apparatus which displays a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, wherein the number of emissions or the intensity is detected; and white balance is corrected by adjusting the amplitudes of the primary color video signals in accordance with the detected number of emissions or the intensity.
The number of emissions or the intensity may be detected from a display ratio of an image produced by the primary color video signals. The white balance correction method may further comprise the step of controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the display ratio of the image. The number of emissions or the intensity may be detected from a display current that flows when displaying an image in accordance with the primary color video signals. The white balance correction method may further comprise the step of controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the image display current.
The number of emissions or the intensity may be detected from an externally applied luminance-adjusting input. The white balance correction method may further comprise the step of controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with the externally applied luminance-adjusting input.
In addition, according to an exemplary embodiment of the present invention, there is provided a white balance correction method for a display apparatus which displays a color image by controlling the number of emissions or the intensity thereof in accordance with primary color video signals input thereto, wherein output gray levels of images represented by the primary color video signals are adjusted in accordance with input gray levels of the images represented by the primary color video signals, thereby correcting white balance which varies with the number of emissions for, or the intensities of, the primary color video signals.
The white balance correction method may further comprise the steps of detecting the input gray levels of the images represented by the primary color video signals; and adjusting the output gray levels of the primary color video signals in accordance with the detected input gray levels. The white balance correction method may further comprise the step of controlling the number of emissions for, or the intensities of, the primary color video signals in accordance with a display ratio or display current of the image.
According to an exemplary embodiment of the present invention, there is provided a white balance correction method for a display apparatus which displays a color image by controlling luminance in accordance with primary color video signals input thereto, wherein an amplitude ratio between the primary color video signals is set in accordance with the luminances of the primary color video signals, thereby suppressing variation of white balance with the luminances.
The luminances of the primary color video signals may be defined by the number of emissions for, or the intensities of, the primary color video signals. A color image may be displayed by means of light-emitting elements in accordance with luminance-defined primary color video signals.
Further, according to an exemplary embodiment of the present invention, there is also provided a white balance correction circuit for use in a display apparatus which displays a color image using primary color video signals, comprising an adjusting unit adjusting the amplitude of each of the primary color video signals; a storage unit storing an amplitude ratios for correcting the amplitudes of the primary color video signals; and a setting unit setting in the adjusting unit amplitude ratios stored in the storage unit wherein the amplitude ratio between the primary color video signals is set in accordance with the number of emissions for, or the intensities of, the primary color video signals, thereby correcting white balance which varies with the number of emissions for, or the intensities of, the primary color video signals.
In addition, according to an exemplary embodiment of the present invention, there is provided a white balance correction circuit for use in a display apparatus which displays a color image using primary color video signals, comprising an adjusting unit adjusting the amplitude of each of the primary color video signals; a computing unit computing an amplitude ratio for each of the primary color video signals from the number of emissions for, or the intensities of, the primary color video signals; and a setting unit setting in the adjusting unit the amplitude ratio computed by the computing unit wherein the amplitude ratio between the primary color video signals is set in accordance with the number of emissions for, or the intensities of, the primary color video signals, thereby correcting white balance which varies with the number of emissions for, or the intensities of, the primary color video signals
The present invention will be more clearly understood from the description of the preferred embodiments as set forth below with reference to the accompanying drawings, wherein:
Before describing in detail the preferred embodiments of the white balance correction circuit, the correction method, and the display apparatus according to an exemplary embodiment of the present invention, a prior art display technique and the problem associated with the prior art will be described with reference to
As shown in
The display panel 10 includes two opposing glass plates, on one of which are arranged the address electrodes 11 and on the other are arranged the scan/sustain electrodes 12 and sustain electrodes 13. The space sandwiched between the two glass plates is partitioned by the barriers 19 into smaller spaces each of which forms a discharge cell.
Each discharge cell is filled with a rare gas such as He—Xe or Ne—Xe. When a voltage is applied to its associated scan/sustain electrode 12 and sustain electrode 13, a discharge occurs, and ultraviolet rays are generated. Each discharge cell has a phosphor coating which glows in red, green, or blue, and the ultraviolet rays excite the phosphor to emit colored light corresponding to the color of the phosphor. By utilizing this light emission and selecting discharge cells of the desired colors in accordance with video signals, a color image can be displayed.
In accordance with the display ratio (or display current) of the image produced by the video signals (three primary color video signals R, G, and B), the drive control circuit 17 controls the number of emissions for the video signals via the scan/sustain pulse output circuit 15 and sustain pulse output circuit 16 so that power consumption does not exceed a predetermined value.
The subfield method is a method that divides one frame into a plurality of subfields (SF1 to SF4) differently weighted according to the difference in the number of emissions, and reproduces a grayscale by selecting for each pixel a subfield appropriate to the signal amplitude representing the pixel.
The driving sequence based on the subfield method shown in
The discharge sustain period T2 of each of the subfields SF1 to SF4 represents the length of time during which the selected cell emits light, and the periods of the respective subfields are weighted in the ratio 8:4:2:1 according to the number of emissions. By selecting an appropriate one of the subfields SF1 to SF4 in accordance with the video signal level, 24=16 gray levels can be reproduced. If it is desired to increase the number of gray levels, the number of subfields is increased; for example, if the number of subfields is increased to 8, 28=256 gray levels can be reproduced. The luminance level of each subfield is controlled by the number of sustain emissions (number of emissions).
As shown in
That is, in
As shown in
In the case of the prior art white balance adjusting circuit, in order to adjust the white balance a prescribed adjustment pattern (for example, a window pattern or the like) is displayed with a specified number of emissions and the amplitudes of the respective color video signals R, G, and B are adjusted so that the desired white balance can be obtained. That is, white balance is adjusted for each set (plasma display apparatus), for example, prior to shipment from the factory; in that case, a prescribed adjustment pattern is displayed with a specified number of emissions and, in that state, the coefficients Kr, Kg, and Kb are stored in the registers in the microcomputer 2.
In the prior art white balance adjusting circuit, since the white balance is adjusted by displaying a prescribed adjustment pattern with a specified APL (that is, with a specified number of emissions), as described above, the white balance may become shifted when the number of emissions (APL) changes.
As shown in
Here, in
Accordingly, at point B where the number of emissions is small, the energy conversion efficiency of the phosphors for the excitation by ultraviolet radiation increases as shown in
Conversely, when displaying an image in accordance with video signals whose APL is lower than that when the white balance was adjusted, the number of emissions may be increased, resulting in a further decrease in the energy conversion efficiency, and causing a difference in white balance because the luminance ratio among red, green, and blue changes, as in the case where the number of emissions is decreased.
Specific embodiments of the white balance correction circuit, the correction method, and the display apparatus according to an exemplary embodiment of the present invention will now be described below with reference to drawings. In the description of the embodiments hereinafter given, a plasma display apparatus is taken as an example, but it will be appreciated that an exemplary embodiment of the present invention is applicable not only to plasma display apparatuses, but also to various other display apparatuses such as display apparatuses using EL elements, FEDs, LED displays, and CRTs.
In
As shown in
For example, consider the case where the white balance is initially adjusted when the number of emissions is largest, and the white balance is corrected relative to its initial value for various values of the number of emissions; in that case, if the luminance of blue is taken as the reference since the blue phosphor has the shortest persistence (that is, the energy conversion efficiency decreases least), the luminance ratios of red, green, and blue, when plotted against the number of emissions, exhibit the characteristics shown in
To maintain the white balance constant regardless of the number of emissions, the rate of change of the luminance ratio should be inversely corrected; therefore, the multiplication coefficient Kg can be calculated as the reciprocal of the luminance ratio α, i.e., Kg=1/α. The multiplication coefficient for red (R) can be calculated similarly. This of course applies if the color used as the reference is changed. In this way, by supplying the multiplication coefficients Kr, Kg, and Kb thus calculated by the microcomputer 2 to the respective multipliers 1 to adjust the signal amplitudes, the luminance ratio and, hence, the white balance can be maintained constant regardless of the number of emissions. In this example, the approximation is performed using a linear equation, but if the approximation is done using an equation of higher degree, a higher correction accuracy can be achieved.
In the present embodiment, first, to determine the characteristics of the phosphors, the relationship between the number of emissions and the luminance is measured, and the number of emissions versus luminance characteristics, such as shown in
More specifically, using the blue phosphor as the reference, the luminance ratio of each phosphor to the blue phosphor is computed. When the luminances of red, green, and blue at point A are denoted by Lar, Lag, and Lab, respectively, and the luminances at a given number of emissions by Lr, Lg, and Lb, respectively, then the normalized results are as shown below.
Luminance ratio of red to blue=(Lr/Lar)/(Lb/Lab)
Luminance ratio of green to blue=(Lg/Lag)/(Lb/Lab)
To suppress the variation of the white balance due to changes in the number of emissions, the luminance ratio should be maintained constant regardless of the number of emissions. Therefore, the change of the luminance ratio is approximated by a linear equation (dashed line: green) as shown in
The linear equation shown in
More specifically, assume for example that the luminances of green and blue at the maximum number of emissions are 200 cd/m2 and 80 cd/m2, respectively, and the luminances at the minimum number of emissions are 60 cd/m2 and 20 cd/m2, respectively.
At this time, the luminance ratio of blue to green at the maximum number of emissions is:
Blue: Green=80:200=1:2.5
Likewise, the luminance ratio of blue to green at the minimum number of emissions is:
Blue: Green=20:60=1:3
The luminance ratio of green to blue is therefore 1.2 (3/2.5); since this value is a0, the multiplication coefficient K as its reciprocal is:
K=1/α0=1/1.2=0.83
That is, the green video signal (G) is corrected by multiplying its signal amplitude by 0.83. The red video signal (R) is also corrected in like manner. In this way, by calculating the multiplication coefficients with various values of the number of emissions by using the previously given approximation equation, and by multiplying the video signals by the respective coefficients, correct white balance can be maintained regardless of the number of emissions.
As shown in
As shown in
More specifically, the current detection circuit 5 detects the current being consumed by the panel drive circuit 6, and converts the current into a voltage value which is supplied to the microcomputer 2; based on the voltage value thus supplied, the microcomputer 2 reads the number of emissions from the number-of-emissions control circuit 7 and sets the number of emissions. Then, the microcomputer 2 computes the change of the luminance ratio due to the rate of change of the energy conversion efficiency corresponding to the thus set number of emissions, and calculates the multiplication coefficients K (Kr, Kg, and Kb) so that the luminance ratio among red, green, and blue is maintained constant. Using the multiplication coefficients Kr, Kg, and Kb, the multipliers 11, 12, and 13 multiply the respective video signals R, G, and B to adjust the amplitudes of the signals so that the white balance is maintained constant.
According to the second embodiment, the invention can be applied to a wide variety of display apparatuses including display apparatuses, such as CRTs, not equipped with an APL detection circuit.
As shown in
More specifically, the APL detection circuit 3 detects the APL of the input video signals and supplies the result to the address decoder 8, and the address decoder 8 generates the address in the ROM 9 at which the multiplication coefficients corresponding to the detected APL are stored. In the ROM 9, the multiplication coefficients Kr, Kg, and Kb for correcting for the change of the luminance ratio due to the change in the energy conversion efficiency are prestored for various values of APL, that is, the number of emissions and, in accordance with the address supplied from the address decoder 8, the corresponding multiplication coefficients are output and supplied to the respective multipliers 11, 12, and 13.
According to the third embodiment, the white balance can be corrected sufficiently even in cases where the number of emissions and the multiplication coefficients Kr, Kg, and Kb cannot be approximated by simple equations (for example, when the energy conversion efficiency of each phosphor varies in a complex manner depending on the number of emissions).
In the third embodiment also, the APL detection circuit 3 may be replaced by the current detection circuit 5, as in the second embodiment, and similar control can be performed by detecting the display current (the current consumption of the panel drive circuit 6) instead of the display ratio.
As shown in
According to the fourth embodiment, as in the third embodiment, the white balance can be corrected sufficiently even in cases where the number of emissions and the multiplication coefficients Kr, Kg, and Kb cannot be approximated by simple equations. Further, in the fourth embodiment also, the APL detection circuit 3 may be replaced by the current detection circuit 5, and similar control can be performed by detecting the display current instead of the display ratio.
As shown in
The white balance correction based on the external luminance-adjusting input according to the fifth embodiment is independent, for example, of the white balance correction in any of the first to fourth embodiments which is performed by detecting the display ratio or the display current, and the white balance correction circuit may be constructed by combining the fifth embodiment with any one of the foregoing embodiments. For example, when the correction circuit is implemented by combining the fifth embodiment with the second embodiment shown in
A technique is known that expresses different gray levels A to F of a plurality of input primary color video signals (for example, three primary color video signals R, G, and B) by different combinations of values of the number of emissions (processes P1 to P5, . . . ) as shown in
More specifically, when reference character F in
As previously described, in the prior art white balance adjusting circuit, to adjust the white balance, a prescribed adjustment pattern (for example, a window pattern or the like) is displayed with specified gray levels, and the signal amplitudes of the respective color video signals R, G, and B are adjusted so that the desired white balance can be obtained. However, when the white balance is adjusted (for example, only once prior to shipment from the factory) by displaying a prescribed adjustment pattern with specified gray levels, the white balance will be shifted if the gray levels (input gray levels) change.
As is apparent from a comparison between the previously given
In
As shown in
Using the input correction coefficients Lr and Lg (Lb), the multipliers 141 and 142 (143) apply corrections in accordance with the following equation and calculate the output gray levels. In the equation, X is the input gray level, Y is the output gray level, and β is the maximum input gray level:
Y(X)=L+(1—L)·(X/β)
Here, when the blue video signal is used as the reference (standard), since Lb=1/αb=1/1=1, there is no need to correct the input gray level of the blue video signal, and therefore, the multiplier 143 for the blue video signal need not be provided.
The sixth embodiment shown in
As is apparent from
Specific embodiments of an exemplary embodiment of the present invention have been described above by taking a plasma display apparatus as an example, but in other color display apparatuses (for example, CRTs, LED displays, etc.) using light emitting elements whose persistence characteristics differ among red, green, and blue, white balance can likewise be corrected by applying an exemplary embodiment of the present invention without modification except that the number of emissions is replaced by the luminance (intensity) of emission.
As described above, according to an exemplary embodiment of the present invention, correct white balance can be maintained regardless of the number of emissions or the intensity of emission.
Many different embodiments of an exemplary embodiment of the present invention may be constructed without departing from the spirit and scope of an exemplary embodiment of the present invention, and it should be understood that an exemplary embodiment of the present invention is not limited to the specific embodiments described in this specification, except as defined in the appended claims.
Number | Date | Country | Kind |
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2000-063991 | Mar 2000 | JP | national |
This application is a continuation application of U.S. application Ser. No. 13/137,694 filed Sep. 2, 2011 now pending that is a continuation application of U.S. application Ser. No. 11/980,623 filed Oct. 31, 2007 that is now patented as U.S. Pat. No. 8,035,578 that is a continuation application of U.S. application Ser. No. 09/722,621 filed Nov. 28, 2000 that is now patented as U.S. Pat. No. 7,439,941, and claims the benefits of Japanese Application 2000-063991 filed Mar. 8, 2000, the disclosures of which are incorporated by reference.
Number | Date | Country | |
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Parent | 13137694 | Sep 2011 | US |
Child | 13618018 | US | |
Parent | 11980623 | Oct 2007 | US |
Child | 13137694 | US | |
Parent | 09722621 | Nov 2000 | US |
Child | 11980623 | US |