The present invention relates to an image-processing device and method for enhancing the luminance and the image quality of display panels. It is an RGBW-color system, which can display a high-quality color and preserve the image-display quality so as to achieve the goals of increasing luminance double, preserving hues and saturation of colors, and preserving the image-contrast quality concurrently.
In recent years, pixels of some panels are composed of four sub-pixels. There are red (R), green (G), blue (B), and white (W) sub-pixels. This RGBW color system can improve the optical efficiency of liquid-crystal displays, where the sub-pixels are arranged as shown in
U.S. Pat. No. 5,929,843 proposed an RGB-to-RGBW image-data converting and processing method as shown in
G′=G
B′=B
W′=min(R, G, B)
Because image colors red (R), green (G), and blue (B) can be enhanced by the white sub-pixel at the same time, the image luminance can be enhanced by way of the above algorithm. However, the drawback of the algorithm is that the hue and saturation of the original image cannot be preserved. This is caused by the same increment of image colors red (R), green (G), and blue (B), which results in the possibility of changing the ratio of the original image colors red (R), green (G), and blue (B). The change can be understood by the following equation:
R:G:B≠(R′+W′):(G′+W′): (B′+W′)
Consequently, the hue and saturation of the image are changed resulting from the ratio of the image colors red (R), green (G), and blue (B) changed. The schematic diagram for color space is shown in
For improving the drawback that although the method proposed by U.S. Pat. No. 5,929,843 enhancing the luminance whereas the hue and saturation of the original image cannot be preserved, U.S. Pat. No. 6,724,934 proposed a new RGB-to-RGBW image-data numerical converting and processing method.
The method used by U.S. Pat. No. 6,724,934 is that classifying in advance according to the numerical relation among red (R), green (G), and blue (B) data of the image pixel. If the data are classified in block B1, as shown in
W′=min(2×R,2×G,2×B)
R′=2×R−W′
G′=2×G−W′
B′=2×B−W′
In
However, if the data are classified in block B2, as shown in
s=1+{min(R,G,B)/[max(R,G,B)−min(R,G,B)]}
W′=min(s×R, s×G, s×B)
R′=s×R−W′
G′=s×G−W′
B′=s×B−W′
In
Nevertheless, although the method proposed by U.S. Pat. No. 6,724,934 not only increases luminance but also preserves hues and saturation of original colors, the drawback of this algorithm is that the extents of increasing luminance for image colors (RGB) in block B1 and block B2 are different. The extent of increasing luminance for image color in block B1 is 2 while the extent of increasing luminance for image color in block B2 is s (wherein 2≧s≧1). Especially for those high-luminance and high-saturation images in block B2, of which the extents of increasing luminance are quite different from the extent of increasing luminance for image color in block B1. Because the extents of increasing luminance for those high-luminance and high-saturation images in block B2 approximate to 1 whereas the extent of increasing luminance for image color in block B1 is 2. This results in a too large variation of the simultaneous contrast, and the quality and effect of the image display are degraded. Especially when those images display high-luminance, high-saturation colors, and high-luminance but tend to white color at the same time, the whole image quality is mostly degraded.
Aim to the aforementioned drawbacks, the Samsung Company proposed a paper named ‘Implementation of RGBW Color System in TFT-LCDs’ in the SID2004 conference. The paper depicted an RGB-to-RGBW image-data numerical converting and processing algorithm of Adaptive White Scaling (AWS).
Please refer to
Accordingly, different images have different luminance-enhancement gains w so as to control the color-distortion value e before and after the luminance enhancement for different images to be lower than the critical value, and to restrain the phenomenon of too large variation of the simultaneous contrast before and after the luminance enhancement for some images.
However, the algorithm depicted in the paper has drawbacks as follows:
Consequently, for solving the abovementioned problems, the main purpose of the current invention is to enhance the luminance of the displayed image color under the condition of retaining the hue and saturation of the original image.
Another purpose of the current invention is to overcome the phenomenon of too large variation of the simultaneous contrast after the luminance enhancement for images so as to enhance the contrast quality and effect of the displayed image after the luminance enhancement.
The present invention has the third purpose that it will not spend complicated and much investment of hardware and image calculation, and it efficiently reduces the operation quantity of the image processing so as to save the investment for circuit hardware.
The fourth purpose of the present invention is that without sacrificing the luminance enhancement, the image-display quality can still be preserved so as to achieve the goals of increasing luminance double, preserving hues and saturation of colors, and preserving the image-contrast quality concurrently.
The present invention is an image-processing device for enhancing the luminance and the image quality of display panels, which is a device and method of RGBW color system for improving the optical efficiency of liquid-crystal displays. The device and method includes a color distribution-calculating unit that classifies the original image-color data. The relation of the colors located in the color space is divided into block Bland block B2 and then calculates the ratio of the color data in any one of block B1 or block B2 to all input image-color data. A control-variable generating unit determines the value of the converting-control variable and the value of the backlight luminance-control variable according to the ratio. The converting-control variable will be output to a data-converting unit, and the data-converting unit converts the original image-color (RGB) data to the new image-color (R′G′B′W′) data according to the converting-control variable. The backlight luminance-control variable will be output to a backlight luminance-control unit so as to control the backlight luminance according to the input backlight luminance-control variable.
The detailed descriptions for contents and the technology of this invention associated with figures are as follows.
Please refer to
The data relation among colors red (R), green (G), and blue (B) in block B1 is: max(R,G,B)/min(R,G,B)≦2, and the data relation among colors red (R), green (G), and blue (B) in block B2 is: max(R,G,B)/min(R,G,B)>2. And then calculate the ratio p for whole input image-color (RGB) data in block B2, where p=(the pixel number of colors in the block B2)/(the total pixel number of the image).
The control-variable generating unit 33 that determines the value of the converting-control variable s and the value of the backlight luminance-control variable b according to the ratio p output by the color distribution calculating unit 32. The converting-control variable s will be output to the RGB-to-RGBW data-converting unit 31, and the backlight luminance-control variable b will be output to the backlight luminance-control unit 34. (The relation among the converting-control variable s, the backlight luminance-control variable b, and the ratio p could be: b=p+1; s=2/(p+1), however, the relation is not restricted to this equation but can be adjusted according to properties of products.)
The data-converting unit 31 will input the original image-color (RGB) data and the converting-control variable s generated by the control-variable generating unit 33, the input data of image color R, G, and B are converted to the output data of image color R′, G′, B′ and W′ according to the converting-control variable s (2≧s≧1). If the colors of the image pixel are located in the block B1, then
W′=min(s×R,s×G,s×B)
R′=s×R−W′
G′=s×G−W′
B′=s×B−W′
If the colors of the image pixel are located in the block B2, then
k=1+(s−1){min(R,G,B)/[max(R,G,B)−min(R,G,B)]}
W′=min(k×R,k×G,k×B)
R′=k×R−W′
G′=k×G−W′
B′=k×B−W′
The image-color processed by this algorithm can preserve the original hues and saturation due to R:G:B=(R′+W′):(G′+W′):(B′+W′).
Moreover, the backlight luminance-control unit 34 controls the backlight luminance of the display panel according to the backlight luminance-control variable b (2≧b≧1). When b equals 1, the backlight luminance is kept at the original value; when b equals 2, the backlight luminance is increased to double of the original value.
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To sum up, comparing the image-processing device and method with the prior image-processing method, the present invention has the following merits:
Comparing the present invention to the paper ‘Implementation of RGBW Color System in TFT-LCDs’ proposed by the Samsung Company, the paper has to calculate the color-distortion value e before and after the luminance enhancement repeatedly so as to obtain the best luminance-enhancement gain w for the input image data. As a result, the method needs complicated and much investment of hardware and image calculation. On the other hand, the image-processing device and method proposed by the present invention calculates the data of colors red R, green G, and blue B of the input image only once so as to find out the ratio of the input image-color located in any block of block B1 or block B2 such that the RGB-to-RGBW data-converting processing can be completed. The present invention efficiently reduces the operation quantity of the image processing, and saves the investment for circuit hardware. Furthermore, without sacrificing the luminance enhancement, the image-display quality can still be preserved by this invention so as to achieve the goals of increasing luminance double, preserving hues and saturation of colors, and preserving the image-contrast quality concurrently.
Number | Date | Country | Kind |
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093141565 | Dec 2004 | TW | national |