Patent Application
20100295865
1. Field of the Invention
The present invention relates to a color sequential display and a display method using the same, more particularly, to a display method that adjusts duration of different color frame periods for displaying.
2. Description of Related Art
Along with the maturation of photoelectric technology and semiconductor manufacturing technology, flat panel displays are developed rapidly. Liquid crystal displays (LCDs) advantageous in low-voltage operation, non-radiation, light weight, and small volume have gradually replaced conventional cathode-ray tube displays to become mainstream display products in the market. An LCD mainly includes a liquid crystal (LC) panel and a backlight module. As liquid crystals injected into the LC panel do not emit light by themselves, the LC panel must be lightened by a plane light source provided by the backlight module so as to enable the LCD to display.
Traditionally, a white light source, e.g., a cold cathode fluorescent lamp (CCFL), is configured in the backlight module for displaying different colors through color filters disposed on each pixel region. There are three color filters, e.g., red, green, and blue, disposed on each pixel region for mixing colors in spatial domain. As a result, not only manufacturing costs are increased, but also light transmission through the color filters is poor. In addition, a color deviation would be perceived by human eyes in boundaries between those color filters, so that a black matrix is employed to separate the color filters for resolving the color deviation problem. However, the light transmission is decreased all the more by the black matrix.
In recent years, light emitting diodes (LEDs) are gradually used to replace the conventional white light source for displaying different colors of a pixel. Instead of mixing colors in a spatial domain, three primary colors of light, e.g., red, green, and blue, emitted by the LEDs are mixed in a temporal domain. In other words, these colors are rapidly switched to display within a visual persistence time interval of human eyes. Hence, there is no need to dispose the color filters, and the light transmission can be efficiently increased.
With regard to the identical optical display times tBR, tBG, and tBB, brightness of the red, green, and blue backlights are different in accordance with currents for driving different color LEDs, and light transmissions of LC correspond to different color backlights. As a result, the frame may not be displayed under a preset white balance. According to the related art, that there are two methods for adjusting the frame to reach the preset white balance.
In the first method, the brightness of one of the red, green, and blue backlights is adjusted to the maximum, and the others are decreased to reach the preset white balance. Nevertheless, as being limited by the attenuated brightness of the backlights, the light source can not achieve its optimal performance. In the second method, under the circumstance that the sub-frame periods TR, TG, and TB are identical, one of the optical display times tBR, tBG, and tBB is adjusted to the maximum, and the other optical display times are decreased to reach the preset white balance. The utilization efficiency of the light source is decreased since the idle time in the sub-frame period can not be efficiently utilized. Besides, the brightness of light perceived by human eyes is related to the duration of the backlight, so that the decrement of the optical display time may cause the displayed frame to have lower brightness.
Accordingly, the present invention provides a display method that can enhance the optical performance and the work efficiency of a color sequential display.
A display method for a color sequential display to display a frame in a frame period is provided. The frame includes a plurality of sub-frames, and the frame period includes a plurality of sub-frame periods corresponding to the sub-frames. In the display method, a first color light source is turned on according to a first duty cycle within a first sub-frame period for displaying a first sub-frame. Next, a second color light source is turned on according to a second duty cycle within a second sub-frame period for displaying a second sub-frame. Finally, the first and the second color light sources are turned on according to a first and a second modified duty cycles within a compensation sub-frame period, respectively, wherein the first modified duty cycle and the second modified duty cycle are proportioned to the first duty cycle and the second duty cycle.
In an embodiment of the foregoing display method, the first duty cycle and the second duty cycle are determined in response to a color temperature of the frame.
In an embodiment of the foregoing display method, a ratio of the first modified duty cycle to the second modified duty cycle is substantially equal to a ratio of the first duty cycle to the second duty cycle.
In an embodiment of the foregoing display method, the first duty cycle is unequal to the second duty cycle.
In an embodiment of the foregoing display method, the first sub-frame period is unequal to the second sub-frame period in accordance with the first duty cycle and the second duty cycle.
In an embodiment of the foregoing display method, the compensation sub-frame period is determined upon the maximum of the first modified duty cycle and the second modified duty cycle.
In an embodiment of the foregoing display method, the display method further includes turning on a third color light source according to a third duty cycle within a third sub-frame period for displaying a third sub-frame.
In an embodiment of the foregoing display method, the first, the second, and the third duty cycles are determined in response to a color temperature of the frame.
In an embodiment of the foregoing display method, the display method further comprises turning on the third color light source according to a third modified duty cycle within the compensation sub-frame period, wherein the third modified duty cycle is proportioned to the third duty cycle.
In an embodiment of the foregoing display method, a ratio of the first modified duty cycle to the third modified duty cycle is substantially equal to a ratio of the first duty cycle to the third duty cycle.
In an embodiment of the foregoing display method, the compensation sub-frame period is determined upon the maximum of the first, the second, and the third modified duty cycles.
In an embodiment of the foregoing display method, colors of the first, the second, and the third color light sources are corresponding to primary colors of light.
A color sequential display is provided in the present invention. The color sequential display displays a frame in a frame period. The frame includes a plurality of sub-frames, and the frame period includes a plurality of sub-frame periods corresponding to the sub-frames. The color sequential display includes a luminaire device, a control module, and a display panel. The luminaire device turns on a first color light source according to a first duty cycle within a first sub-frame period. Next, the luminaire device turns on a second color light source according to a second duty cycle within a second sub-frame period, and the luminaire device turns on the first and the second color light sources respectively according to a first modified duty cycle and a second modified duty cycle within a compensation sub-frame period. The control module determines the first modified duty cycle and the second modified duty cycle respectively proportioned to the first duty cycle and the second duty cycle. The display panel displays a first, a second, and a compensation sub-frames in response to the luminaire device during the first, the second, and the compensation sub-frame periods, respectively.
In an embodiment of the foregoing color sequential display, the control module determines the first duty cycle and the second duty cycle in response to a color temperature of the frame.
In an embodiment of the foregoing color sequential display, a ratio of the first modified duty cycle to the second modified duty cycle is substantially equal to a ratio of the first duty cycle to the second duty cycle.
In an embodiment of the foregoing color sequential display, the first duty cycle is unequal to the second duty cycle.
In an embodiment of the foregoing color sequential display, the first sub-frame period is unequal to the second sub-frame period in accordance with the first duty cycle and the second duty cycle.
In an embodiment of the foregoing color sequential display, the compensation sub-frame period is determined upon the maximum of the first modified duty cycle and the second modified duty cycle.
In an embodiment of the foregoing color sequential display, the luminaire device further turns on a third color light source according to a third duty cycle within a third sub-frame period, and the display panel displays a third sub-frame during the third sub-frame period.
In an embodiment of the foregoing color sequential display, the luminaire device further turns on the third color light source according to a third modified duty cycle within the compensation sub-frame period, and the control module determines the third modified duty cycle proportioned to the third duty cycle.
The present invention provides the display method and the color sequential display that refer to the color temperature of the frame to determine the duration of the duty cycles and the compensation duty cycles during the compensation sub-frame periods. For achieving white balance, the compensation duty cycles are proportioned to the duty cycles in response to the color temperature of the frame. Hence, the optical performance of the color sequential display can be enhanced.
In order to make the aforementioned features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.
It is to be understood that both the foregoing general description and the following detailed description are exemplary, and are intended to provide further explanation of the invention as claimed.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
The color sequential display 200 includes a display panel 210, a luminaire device 220, and a control module 230. In the embodiment of the present invention, it is assumed that the sub-frames of red, green, blue and the compensation sub-frame are sequentially displayed. As shown in
Referring to
Similarly, analogies can be drawn to display a green sub-frame G and a blue sub-frame B. After the LC response time tLC, the luminaire device 220 turns on a green color light source according to the green duty cycle DG within the green sub-frame period 112, so that the display panel 210 displays the green sub-frame G, and after the LC response time tLC, the luminaire device 220 turns on a blue color light source according to the blue duty cycle DB within the blue sub-frame period 113, so that the display panel 210 can display the blue sub-frame B.
In the embodiment of the invention, the red duty cycle DR, the green duty cycle DG, and the blue duty cycle DB are determined by the control module 230, and the red duty cycle DR, the green duty cycle DG, and the blue duty cycle DB are in response to a color temperature of the frame so as to achieve a white balance of the frame. Generally, a color temperature is a significant characteristic of visible light, and the color perceived by human eyes varies with the color temperature. The color temperature can be referred to as adjusting the duty cycles, so that variations in the embodiment can be adapted to different light sources. Note that in the embodiment, the red duty cycle DR is unequal to the green duty cycle DG, and the sub-frame period 111 is unequal to the sub-frame period 112 in accordance with the red duty cycle DR and the green duty cycle DG. Since the sub-frame periods can be adjusted in accordance with the duty cycle, an idle time in the sub-frame period can be efficiently utilized. Hence, the color sequential display 200 can achieve the white balance by adjusting the duration of the duty cycles upon which the sub-frames are regulated, so that the optical performance and the work efficiency of the color sequential display 200 can be enhanced.
Besides, the embodiment of the control module 230 determines a red modified duty cycle DR′, a green modified duty cycle DG′, and a blue modified duty cycle DB′ respectively proportioned to the red duty cycle DR, the green duty cycle DG, and the blue duty cycle DB. After the control module 230 determines the red modified duty cycle DR′, the green modified duty cycle DG′, and the blue modified duty cycle DB′, the luminaire device 220, e.g., a light emitting diode (LED), respectively turns on the red color light source, the green color light source, and the blue color light source according to the red modified duty cycle DR′, the green modified duty cycle DG′, and the blue modified duty cycle DB′ during the compensation sub-frame period 114. Hence, the display panel 210 displays the compensation sub-frame during the compensation sub-frame period 114. In the embodiment, the compensation sub-frame is substantially a white sub-frame so as to decrease a color breakup (CBU) of the frame, and the white sub-frame in this embodiment is composed of a red compensation sub-frame R′, a green compensation sub-frame G′, and a blue compensation sub-frame B′.
Specifically, the red modified duty cycle DR′, the green modified duty cycle DG′, and the blue modified duty cycle DB′ can be designed according to following equations:
D
R
′=D
R
×D %
D
G
′=D
G
×D %
D
B
′=D
B
×D %
, where 0≦D≦100 and D is a ratio of the modified duty cycle to the duty cycle. In the embodiment, a ratio of the red modified duty cycle DR′ to the green modified duty cycle DG′ is substantially equal to a ratio of the red duty cycle DR to the green duty cycle DG. Similarly, a ratio of the red modified duty cycle DR′ to the blue modified duty cycle DB′ is substantially equal to a ratio of the red duty cycle DR to the blue duty cycle DB. In addition, the compensation sub-frame period 114 in the present embodiment is determined upon the maximum of the red modified duty cycle DR′, the green modified duty cycle DG′, and blue modified duty cycle DB′. That is, compensation sub-frame period 114=Max (DR′, DG′, DB′). For example, if the green modified duty cycle DG′ is the maximum of the red modified duty cycle DR′, the green modified duty cycle DG′, and blue modified duty cycle DB′ (as shown in
Certainly, since the compensation sub-frame period 114 is determined upon the maximum of the red modified duty cycle DR′, the green modified duty cycle DG′, and blue modified duty cycle DB′ which are respectively determined upon the red duty cycle DR, the green duty cycle DG, and the blue duty cycle DB, it is merely required to adjust the red duty cycle DR, the green duty cycle DG, and the blue duty cycle DB so as to achieve the white balance of the frame, which greatly reduces difficulties in an adjustment. More specifically, if the white color presented by the frame is slightly blue, the green duty cycle DB is reduced to achieve the white balance of the frame, and so is the blue modified duty cycle DB′ during the compensation sub-frame period 114. In addition, since the brightness of light perceived by human eyes is related to the duration of the backlight (i.e. the duty cycle and the modified duty cycle), the brightness (intensity) of the compensation sub-frame and the brightness (intensity) of the red, green, and blue sub-frames may be adjusted to the same by adjusting the red modified duty cycle DR′ to be equal to the red duty cycle DR, by adjusting the green modified duty cycle DG′ to be equal to the green duty cycle DG, and by adjusting the blue modified duty cycle DB′ to be equal to the blue duty cycle DB. In other words, the brightness (intensity) can be enhanced by adjusting the ratio of the red modified duty cycle DR′ to the red duty cycle DR to be 100% (i.e D %=100%), by adjusting the ratio of the green modified duty cycle DG′ to the green duty cycle DG to be 100%, and by adjusting the ratio of the blue modified duty cycle DB′ to the blue duty cycle DB to be 100%, and the intensity of the compensation sub-frame and the red, green, and blue sub-frames would be the same. Hence, the intensity of the compensation sub-frame can be increased or decreased by increasing or decreasing the ratio of the red modified duty cycle DR′ to the red duty cycle DR, the ratio of the green modified duty cycle DG′ to the green duty cycle DG, or the ratio of the blue modified duty cycle DB′ to the blue duty cycle DB.
Thereafter, step S104 is carried out. The third (blue) color light source is turned on according to a third duty cycle (the blue duty cycle DB) within a third sub-frame period (the sub-frame period 113) for displaying a third (blue) sub-frame. Note that the color of the first color light source can be another color (e.g. green, blue, and so on) in another embodiment, which can also be applied to the color of the second color light source and the color of the third color light source.
Next, step S106 is carried out. The first (red) color light source according to a first modified duty cycle (the red modified duty cycle DR′) and the second (green) color light source according to a second modified duty cycle (the green modified duty cycle DG′) are respectively turned on within a compensation sub-frame period (the compensation sub-frame period 114) for displaying a compensation sub-frame, wherein the first modified duty cycle (the red modified duty cycle DR′) and the second modified duty cycle (the green modified duty cycle DG′) are proportioned to the first duty cycle (the red duty cycle DR) and the second duty cycle (the green duty cycle DG), respectively.
Finally, step S108 is carried out. The third (blue) color light source is turned on according to a third modified duty cycle (the blue modified duty cycle DB′) within the compensation sub-frame period (the compensation sub-frame period 114), wherein the third modified duty cycle (the blue modified duty cycle DB′) is proportioned to the third duty cycle (the blue duty cycle DB).
Note that if only the first and the second color light sources are provided in another embodiment, the step S104 and the step S108 can be skipped. That is, although there are four sub-frames described in the said embodiment, people having ordinary skill in the art can, according to the color sequential display method, utilize more or less sub-frames in comparison with said embodiment. Therefore, the present invention is not limited to the displaying order of the sub-frames, the number of the sub-frames, and colors of the sub-frames. Note that although there are four color sub-frame periods 111 through 114 as described in the embodiment, the sub-frame periods in other numbers can also be applicable in another embodiment. In addition, the number of the sub-frame period is equivalent to the number of the sub-frame.
In summary, said embodiments in
Though the present invention has been disclosed above by the preferred embodiments, they are not intended to limit the present invention. Anybody skilled in the art can make some modifications and variations without departing from the spirit and scope of the present invention. Therefore, the protecting range of the present invention falls in the appended claims.
