This application claims priority to Taiwan Patent Application Serial Number 96142738, filed Nov. 12, 2007, which is herein incorporated by reference.
The present invention relates to an LCD driving method, and more particularly to a driving method for a field sequential LCD backlight.
Generally, methods for driving an LCD can be classified into two methods, the color filter method and the field-sequential driving method, based on methods of displaying color images.
According to the color sequential method, three primary colors are sequentially switched within the time that humans percept the flicker of image to compose a color. That is, the primary colors are sequentially displayed in three time segments. Therefore, a complete color image is displayed as a rapidly changing sequence of primary monochrome images. Since every pixel unit in the display contributes to every primary image, a color sequential imaging display must address the pixel units first to select required pixel units to display. Since three primary colors are sequentially switched in three time segments in the color sequential method, a color difference exists between the moving object's head and tail, called color break-up; that may reduce the display quality. When a white color image moves from right side to left side, human eyes may catch up with this image. However, due to the vision persistence effect, a trailing image whose front end is red color and rear end is blue color is projected onto the retina.
Therefore, improving the image quality is one of the targets waiting for being solved.
One of the purposes of the present invention is to provide a color sequential method for a liquid crystal display to resolve the color breakup problem.
Accordingly, one aspect of the present invention provides a color sequential method for driving a backlight module of a liquid crystal display. The backlight module includes three light sources, a first light source, a second light source, and a third light source, and each illuminates different color light respectively. The method includes sequentially turning on the three light sources, wherein the first light source and the second light source are turned on twice and the third light source is turned on once.
The frequency of switching the red, green and blue color light source is increased to resolve the color breakup problem. Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
As shown in
According to this embodiment, the same color light source is turned on in the third sub-frame and the fourth sub-frame. For example, the blue color light source is turned on in the third sub-frame and the fourth sub-frame. However, in another embodiment, the other color light source can be turned on in the third sub-frame and the fourth sub-frame. Accordingly, since the blue color light source is turned on in the continuous third sub-frame and fourth sub-frame, only one addressing interval 301 and one waiting interval 302 are required. Moreover, since only one addressing interval 301 and one waiting interval 302 are required, the time period for keeping the blue color light source in turning on state could be less than twice the period for keeping the green color (or red color) light source in turning on state but larger than the period for keeping the green color (or red color) light source in turning on state.
Accordingly, the order for displaying the display data in the position from m pixel to m+7 pixel within the n−1 frame is as follows. In the red sub-frame (R-SF), red display data is displayed. In the green sub-frame (G-SF), green display data is displayed. In the blue sub-frame (B-SF), blue display data is displayed. In the green sub-frame (G-SF), green display data is displayed. In the red sub-frame (R-SF), red display data is displayed.
Moreover, the order for displaying the display data in the position from m+6 pixel to m+13 pixel within the n frame is as follows. In the green sub-frame (G-SF), green display data is displayed. In the blue sub-frame (B-SF), blue display data is displayed. In the red sub-frame (R-SF), red display data is displayed. In the blue sub-frame (B-SF), blue display data is displayed. In the green sub-frame (G-SF), green display data is displayed. By sequentially showing the three primary colors, red color, green color and blue color, in the persistence of vision time, color display may be reached.
When such an image is observed, the observer views the image while shifting his or her view point following the shift of the image. Therefore, the observer has to shift his or her view point six pixels for each frame in the shifting direction of the image, as illustrated in the
In this embodiment, each frame includes five sub-frames. Therefore, in a frame, the red light source and the green light source are turned on twice and the blue light source is turned on once. However, in another embodiment, the light source that is turned on once also can select the red light or green light. By sequentially showing three primary colors in the persistence of vision time, any color can be created by mixing the three primary colors. Since the frequency to sequentially turn on the light source is raised, three primary colors may appear two times within a frame. In other words, the three primary colors are overlapped in the (m−6) to (m+7) pixels. Therefore, as illustrated in
Moreover, in this embodiment, same color light source is turned on in the continuous third sub-frame and fourth sub-frame. Therefore, the third sub-frame and fourth sub-frame are combined together to be as a sub-frame. That is that only one addressing interval and one waiting interval are required. Compared with the conventional double frame rate requiring six sub-frames, only five sub-frames are required in the present invention to reach the double frame rate effect. Therefore, each sub-frame occupies a longer time period in a frame. The increased time period is used as the waiting interval for the response time of the liquid crystal. On the other hand, the frame rate is higher than 60 Hz, which can improve the color breakup phenomenon.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
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