1. Field of the Invention
The present invention relates to a display device which lowers the chroma of a display image, thereby to attain the power saving of backlight.
2. Description of the Related Art
It is desired of a liquidcrystal display device to reduce the power of backlight for power saving. It is stated in JPA1165531 that, in order to attain lowered power with the degradation of an image suppressed, image data are adjusted so as to raise the transmission factor of a liquidcrystal display screen, whereupon the luminance of the backlight is lowered to a corresponding degree. Concretely, using the maximum gray level or histogram of the image data, a gray level at which cumulative frequencies from the maximum gray level arrive at a fixed rate is detected by a data analysis unit, and this gray level is outputted as a threshold gray level. A backlight control unit reduces the backlight luminance to a display luminance at the detected threshold gray level. In interlocking with the backlight control unit, a data adjustment unit converts the image data whose gray levels are from “0” to the threshold gray level, into digital signals of full scale. Thus, it is intended to attain the lowered power without degrading an image of high luminance and high chroma.
In case of the image of high luminance/high chroma, however, the threshold gray level becomes high, and hence, the effect of reducing the luminance of the backlight is low. Especially in a case where the luminance of characters is high is a game screen or the like, the threshold gray level becomes high even when the luminance of the image itself is low, so that the backlight luminance cannot be reduced. Therefore, a power reduction effect based on the backlight adjustment interlocked with the image becomes low on the average, in a display device in a field where the image of high luminance/high chroma is outputted in many chances.
Therefore, the present invention has for its object to provide a display device of high luminance/high chroma in which the chroma less influencing the sense of sight is lowered, thereby to make an image degradation inconspicuous and to heighten a power reduction effect based on a backlight adjustment interlocked with an image.
The invention is characterized in that a chroma control unit for lowering the chroma of input image data is disposed in a display device. In the chroma control unit, by way of example, the image data of RGB format as the input image data are once converted into a YUV (or YCbCr) format, and only the chroma (U, V (or Cb, Cr)) being color information is lowered. Thereafter, that signal of the YUV (or YCbCr) format whose chroma has been lowered is converted into the signal of the RGB format again. Besides, the input image data of the RGB format are directly converted so as to change into a gray scale. A histogram is generated from the data processed by the chroma control unit in this manner, an image adjustment parameter is generated on the basis of the histogram, and a backlight adjustment interlocked with an image is performed by an image expansion unit and a backlight control unit.
The chroma of the input image data is lowered by the chroma control unit, whereby the maximum value in pixel units (the highest gray level data in RGB) lowers in pixels having chroma values. Thus, the maximum gray level of the image and the distribution of the histogram shifts onto a low gray level side. Since the shift becomes lower than a threshold gray level in the prior art, the effect of reducing a backlight luminance can be heightened even in an image featuring a high luminance/a high chroma. In the case of heightening the power reduction effect of backlight in this manner, the chroma which is lower in sensitivity than the luminance in the sense of sight is discarded in the invention, and hence, an image degradation lessens. Moreover, since the conversion for lowering the chroma is used in only the chroma control unit, a high precision becomes unnecessary, and the invention can be realized in a saved circuit scale.
Now, the best mode for carrying out the present invention will be described with reference to the drawings.
In this embodiment, in the image processing unit 2, the input image data RiGiBi being an RGB signal are converted into a YUV signal, the chroma UV of the YUV signal is multiplied by the chroma coefficient Csc, and the resulting YUV signal is converted into the output image data RoGoBo being the RGB signal, again. The degree to which the chroma UV is lowered, is adjusted by the chroma coefficient Csc. Besides, the degree of power reduction is determined by the power reduction parameter Psc. Here, the letter “Y” of the YUV signal signifies a luminance signal, the letter “U” signifies the difference between the luminance signal and a blue component, and the letter “V” signifies the difference between the luminance signal and a red component.
The YsUsVs signal of the lowered chroma is converted into the RGB signal again, whereby the maximum value of three pixels RsGsBs after the conversion becomes lower in the gray level than the maximum value of three pixels RiGiBi. However, this applies only in a case where the original pixels have chroma values.
Next, referring to
A histogram counting unit 203 sets eight gray level ranges Hs1, Hs2, . . . , and Hs8 for the pixel information Ps as shown in
An image adjustment parameter generation unit 204 generates the image adjustment parameter Th in accordance with the frequencies Cnt of the individual gray level ranges as outputted from the histogram counting unit 203, and the power reduction parameter Psc.
A flow chart on that occasion is shown in
At the step e, using the power reduction parameter Psc (0≦Psc<1), “Call” which is the summation (constant) of the frequencies Cnt of one frame is multiplied by (1−Psc). In a case where the power reduction parameter Psc=0 holds, the frequencies Cnt up to the gray level range Hs8 are counted, and any gray level data are not discarded, but a power reduction rate is zero. In a case where the power reduction parameter Psc is less than one, gray level data on a high gray level side are discarded in accordance with the value of the parameter Psc, and a power reduction effect is attained.
At the next step f, the value of the counter “i” at the step e is written into the number “ips” of a gray level region, and the parameter generation is ended at a step g.
The image adjustment parameter Th for selecting the gray level region Hs(ips) of the histogram is generated on the basis of the number “ips” of the gray level region thus obtained.
An image expansion unit 205 shown in
Besides, the backlight control unit 4 shown in
In this embodiment, the input image data RiGiBi exceeding the image adjustment parameter Th are discarded by the image expansion unit 205, and the nondiscarded input image data RiGiBi are expanded to the full scale so as to generate the output image data RoGoBo. Therefore, even when the backlight luminance is lowered to B(Th), the luminance in the display image does not change. In this way, the backlight control unit 4 outputs the control signal Blc so that the backlight luminance may become B(Th) in accordance with the image adjustment parameter Th.
As thus far described, even when the backlight luminance is lowered to B(Th), the input image data at the gray levels of “0” to “Th” are expanded to the output image data RoGoBo of the full scale at the gray levels of “0” to “255” by the image expansion unit 205, so that a display conforming to the input image data can be realized at the low power with the image degradation suppressed. Here, the power reduction parameter Psc is set so as to prevent the image degradation from appearing.
In this embodiment, in the case where the histogram is generated, it may well be generated except a color (in general, blue B) whose color characteristics of high gray levels do not greatly influence the sense of sight, or it may well be generated with a specified color (for example, green G) which influences sight characteristics.
This embodiment is the same as Embodiment 1 entirely in the configuration of the display device, but it differs in the chroma lowering method in the chroma conversion unit 207 shown in
In the configuration of a display device, this embodiment differs from Embodiment 1 in the configuration of a chroma conversion unit included in the chroma control unit 201, and in the chroma lowering method in the chroma conversion unit.
In this embodiment, chroma coefficients Csc are respectively set in accordance with the maximum gray level data of the individual pixels of the input image data RiGiBi. By way of example, a chroma coefficient Csc1 is used in a case where the maximum gray level data RiGiBi_max of the individual pixels is, at most, m1, and a chroma coefficient Csc2 is used in a case where the maximum gray level data RiGiBi_max of the individual pixels is above m1 and below m2. Also in this case, as in Embodiment 2, chroma values are greatly decreased in case of pixels of high luminance, and they are little decreased in case of pixels of low luminance, whereby the suppression of the degradation of a color can be expected.
In the embodiments thus far described, the input RGB signal has been once converted into the YUV signal so as to control the chroma, by the chroma control unit 201 shown in
In this embodiment, the input RGB signal is directly converted so as to control the chroma.
Rs=Csc*Ri+(1−Csc)/2*Gi+(1−Csc)/2*Bi
Gs=(1−Csc)/2*Ri+Csc*Gi+(1−Csc)/2*Bi
Bs=(1−Csc)/2*Ri+(1−Csc)/2*Gi+Csc*Bi FORMULAS 1
Number | Date | Country | Kind |
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2007-211743 | Aug 2007 | JP | national |
The present application is a continuation application U.S. application Ser. No. 12,155,951, filed Jun. 12, 2008, and which application claims priority from Japanese application serial no. 2007211743 filed on Aug. 15, 2007, the contents of which are hereby incorporated by reference into this application.
Number | Date | Country | |
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Parent | 12155951 | Jun 2008 | US |
Child | 13929344 | US |