This application claims the benefit of Taiwan application Serial No. 95101483, filed Jan. 13, 2006, the subject matter of which is incorporated herein by reference.
1. Field of the Invention
The invention relates in general to a LCD (Liquid Crystal Display) panel, and more particularly to a LCD panel having low color differences and multiple domains.
2. Description of the Related Art
The viewable angle of a typical LCD is not large, so the colors of the frame become incorrect when the display is viewed at a large tilt angle. The LCD with the larger screen suffers from the drawback of the uneven brightness over the middle and periphery portions of the frame. Thus, manufacturers have paid a great deal of attention to the development of various LCDs with wide viewing angles, such as an IPS (In-Plane Switching) LCD, a MVA (Multi-domain Vertical Alignment) LCD, and the like.
In the MVA LCD, one pixel is divided into a plurality of domains. Arranging directions of liquid crystal molecules in each domain are slightly different from one another such that the difference is not too great when the display is viewed with different viewing angles.
However, the colors of the frame of the multi-domain LCD viewed with different viewing angles still exhibit some differences, so the frame quality thereof requires further improvement.
In a conventional driving method of solving the color difference, one pixel in the LCD panel is divided into two sub-pixels each having a thin film transistor for control. Thus, the slightly different driving voltages may be respectively inputted to the two sub-pixels of the pixel so that the phenomenon of the color difference can be improved.
The invention is directed to a multi-domain LCD, which has the low color differences and the enhanced frame quality.
According to the present invention, a LCD (Liquid Crystal Display) panel includes data lines, scan lines and pixels. Each pixel includes a first sub-pixel and a second sub-pixel, which respectively have a first storage capacitor and a second storage capacitor. A first data switch is selectively coupled to a first terminal of the first storage capacitor and one of the data lines. A second data switch is selectively coupled to a first terminal of the second storage capacitor and one of the data lines. A first bias line is coupled to a second terminal of the first storage capacitor. A second bias line is coupled to a second terminal of the second storage capacitor. When the scan line is enabled, the first data switch and the second data switch turn on such that the signal on the data line is transmitted to the first sub-pixel and the second sub-pixel. Next, after the scan line is disabled, levels of the first bias line and the second bias line are respectively changed such that pixel voltages of the first sub-pixel and the second sub-pixel slightly different from each other.
The invention will become apparent from the following detailed description of the preferred but non-limiting embodiments. The following description is made with reference to the accompanying drawings.
First Embodiment
The pixel 101 includes a first sub-pixel 1011 and a second sub-pixel 1012. The first sub-pixel 1011 includes a thin film transistor 10111, a storage capacitor Cst1, and a parasitic capacitor Cgs1 formed between a gate and a source of the thin film transistor 10111. The thin film transistor 10111 has the gate coupled to the scan line S(1), the drain coupled to the data line D(1) and a source coupled to a first terminal of a liquid crystal equivalent capacitor Clc1 and a first terminal of the storage capacitor Cst1. The potential of the source of the thin film transistor 10111 is vs1, a second terminal of the liquid crystal equivalent capacitor Clc1 is coupled to a common electrode having the voltage of Vcom, and a second terminal of the storage capacitor Cst1 is coupled to the first bias line B1(1). The second sub-pixel 1012 includes a thin film transistor 10121, a liquid crystal equivalent capacitor Clc2, a storage capacitor Cst2 and a parasitic capacitor Cgs2 formed between the gate and the source of the thin film transistor 10121. The thin film transistor 10121 has a gate coupled to the scan line S(1), a drain coupled to the data line D(1), and a source coupled to a first terminal of the liquid crystal equivalent capacitor Clc2 and a first terminal of the storage capacitor Cst2. The potential of the source of the thin film transistor 10121 is vs2, a second terminal of the liquid crystal equivalent capacitor Clc2 is coupled to the common electrode having the voltage of Vcom, and a second terminal of the storage capacitor Cst2 is coupled to the first bias line B2(1). The storage capacitor Cst1 of the first sub-pixel 1011 is formed by the source of the thin film transistor 10111 and the first bias line B1(n), and the storage capacitor Cst2 of the second sub-pixel 1012 is formed by the source of the thin film transistor 10121 and the second bias line B2(n).
There are many methods of enabling the first sub-pixel and the second sub-pixel to generate different pixel voltages, and only two examples are illustrated in connection with this embodiment.
and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed from (Vd1−Vcom) to
This phenomenon is referred to as a feed-through effect. At time t2, the voltage of the first bias line B1(1) is changed from Vbh to Vbl, and the voltage of the second bias line B2(1) is changed from Vbl to Vbh. At this moment, the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed from (Vd1−Vcom−Δvft1) to (Vd1−Vcom−Δvft1−Δvst1) due to the feed-through effect, wherein
and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to
At time t3 in the second frame time period f2, the voltage of the first bias line B1(1) is Vbl, the voltage of the second bias line B2(1) is Vbh, and the voltage of the scan line S(n) is Vgh to make the thin film transistor 10111 and the thin film transistor 10121 turn on. The source driver 102 transfers a display voltage Vd2 (not shown) to the liquid crystal equivalent capacitor Clc1 and the liquid crystal equivalent capacitor Clc2 through the data line D(1). The charging effect of the capacitor makes the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 change to (Vd2−Vcom) slowly, and makes the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 to change to (Vd2−Vcom). At time t4, the voltage of the first bias line B1(1) is Vbl, the voltage of the second bias line B2(1) is Vbh, and the voltage of the scan line S(n) is Vgl to make the thin film transistor 10111 and the thin film transistor 10121 cut off. At this moment, because the voltage difference between two terminals of each of the parasitic capacitor Cgs1, and the parasitic capacitor Cgs2 has to be kept constant, the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 is changed to (Vd2−Vcom−Δvft1), and the voltage difference Vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd2−Vcom−Δvft2). At time t5, the voltage of the first bias line B1(1) is changed from Vbl to Vbh, and the voltage of the second bias line B2(1) is changed from Vbh to Vbl. At this moment, because the voltage difference between two terminals of each of the storage capacitor Cst1 and the storage capacitor Cst2 has to be kept constant, the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 is changed to (Vd2−Vcom−Δvft1+Δvst1), and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd2−Vcom−Δvft2−Δvst2).
In the first frame time period f1, the driving method makes the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 of the first sub-pixel 1011 assume a value of (Vd1−Vcom−Δvft1−Δvst2) and makes the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 of the second sub-pixel 1012 assume a value of (Vd1−Vcom−Δvft2+Δvst2). With this the voltage differences between two terminals of the liquid crystal equivalent capacitors of the first sub-pixel and the second sub-pixel are different from each other and the low color difference effect can be achieved. Similarly, in the second frame time period f2, the driving method causes the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 of the first sub-pixel 1011 to become (Vd2−Vcom−Δvft1+Δvst1) and causes the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 of the second sub-pixel 1012 to become (Vd1−Vcom−Δvft2−Δvst2), such that the voltage differences between two terminals of the liquid crystal equivalent capacitors of the first sub-pixel 1011 and the second sub-pixel 1012 are slightly different from each other and the low color difference effect can be achieved. It is appreciated that, in the first frame time period f1 and the second frame time period f2, the voltage differences between two terminals of the liquid crystal equivalent capacitors of the first sub-pixel 1011 and the second sub-pixel 1012 are kept constant except that the voltage differences change as the capacitors are charged and at B1(1) and B2(1). Thus, the frame stability can be held.
At time to in the first frame time period f1, the voltage of the first bias line B1(1) increases from Vcom to Vbh, the voltage of the second bias line B2(1) decreases from Vcom to Vbl, and the voltage of the scan line S(n) is Vgh. Thus, the thin film transistor 10111 and the thin film transistor 10121 turn on, and the source driver 102 transfers the display voltage Vd1 (not shown) to the liquid crystal equivalent capacitor Clc1 and the liquid crystal equivalent capacitor Clc2 through the data line D(1). The capacitor charging effect enables the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 to change to (Vd1−Vcom) slowly, and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 to change to (Vd1−Vcom) slowly. So, the voltage of the first bias line B1(1) is still Vbh, the voltage of the second bias line B2(1) is still Vbl and the voltage of the scan line S(n) is Vgl at time t1, such that the thin film transistor 10111 and the thin film transistor 10121 cut off. At this moment, the voltage difference vdif1 between two terminals of liquid crystal equivalent capacitor Clc1 is changed from (Vd1−Vcom) to (Vd1−Vcom−Δvft1) due to the feed-through effect, wherein
and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed from (Vd1−Vcom) to (Vd1−Vcom−Δvft2), wherein
Later, at time t2, the voltage of the first bias line B1(1) decreases from Vbh to Vcom, the voltage of the second bias line B2(1) increases from Vbl to Vcom. At this moment, due to the feed-through effect, the voltage difference vdif1 between two terminals of liquid crystal equivalent capacitor Clc2 is changed from (Vd1−Vcom−Δvft1) to (Vd1−Vcom−Δvft1−Δvst1′), wherein
and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd1−Vcom−Δvft2+Δvst2′), wherein
At time t3 in the second frame time period f2, the voltage of the first bias line B1(1) decreases from Vcom to Vbl, the voltage of the second bias line B2(1) increases from Vcom to Vbh, and the voltage of the scan line S(n) is Vgh such that the thin film transistor 10111 and the thin film transistor 10121 turn on. The source driver 102 transfers the display voltage Vd2 (not shown) to the liquid crystal equivalent capacitor Clc1 and the liquid crystal equivalent capacitor Clc2 through the data line D(1). Due to the capacitor charging effect, the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 is changed to (Vd2−Vcom) slowly, and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd2−Vcom) slowly. At time t4, the voltage of the first bias line B1(1) is still Vbl, the voltage of the second bias line B2(1) is still Vbh and the voltage of the scan line S (n) is still Vgl such that the thin film transistor 10111 and the thin film transistor 10121 cut off. At this moment, due to the feed-through effect, the voltage difference Vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 is changed to (Vd2−Vcom−Δvft1), and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd2−Vcom−Δvft2). Later, at time t5, the voltage of the first bias line B1(1) increases from Vbl to Vcom, the voltage of the second bias line B2(1) decreases from Vbh to Vcom. At this moment, due to the feed-through effect, the voltage difference vdif1 between two terminals of the liquid crystal equivalent capacitor Clc1 is changed to (Vd2−Vcom−Δvft1+Δvst1′), and the voltage difference vdif2 between two terminals of the liquid crystal equivalent capacitor Clc2 is changed to (Vd2−Vcom−Δvft2−Δvst2′).
The first and second driving methods assume the phase difference of 180 degrees between the levels of the first bias line B1(1) and the second bias line B2(1), so the voltage differences between two terminals of the liquid crystal equivalent capacitors of the first sub-pixel 1011 and the second sub-pixel 1012 are slightly different from each other, and the low color difference effect can be achieved.
In addition to the 180 degrees of this embodiment, the phase difference between the first bias line B1(1) and the second bias line B2(1) may also range from 180 to 360 degrees. In addition, in one frame time period, the number of switching time(s) of the first bias line B1(1) and the second bias line B2(1) is one in this embodiment but may be two or more than two in other embodiments.
It is appreciated that, in the first frame time period f1 and the second frame time period f2, the voltage differences between two terminals of the liquid crystal equivalent capacitors of the first sub-pixel 1011 and the second sub-pixel 1012 are kept constant except that the voltage differences change as the capacitors are charged. Thus, the frame stability can be held.
Second Embodiment
The pixel 401 includes a first sub-pixel 4011 and a second sub-pixel 4012. The first sub-pixel 4011 includes a thin film transistor 40111, a liquid crystal equivalent capacitor Clc1 and a storage capacitor Cst1. The second sub-pixel 4012 includes a thin film transistor 40121, a liquid crystal equivalent capacitor Clc2 and a storage capacitor Cst2.
The difference between the LCD panel 400 of the second embodiment and the LCD panel 100 of the first embodiment will be described in the following. Two adjacent bias lines B are merged into one bias line in the LCD panel 400. That is, one bias line B of the LCD panel 400 simultaneously adjusts the second sub-pixel of an upper pixel and the first sub-pixel of a lower pixel. Thus, the number of the bias lines may be reduced to one half. The phases of the voltages of the adjacent bias line B(n) and bias line B(n+1) are different from each other.
The difference between the signal waveform (
At time t3 in the second frame time period f2, the voltage of the bias line B(n+1) is Vbh and the voltage of the scan line S(n) is Vgh such that the thin film transistor 40111 and the thin film transistor 40121 turn on. At time t4, the voltage of the bias line B(n+1) is still Vbh and the voltage of the scan line S(n) is decreased to Vgl such that the thin film transistor 40111 and the thin film transistor 40121 cut off. It will be appreciated that the disabled scan line S(n) cannot directly and immediately reduce the voltage of the bias line B, as shown in
Method of Driving Bias Lines
The bias lines may be driven by a gate driver or a logic circuit in this example. However, one of ordinary skill in the art may achieve the driving method of the invention according to any other arbitrary device or method.
Hereinafter, a LCD using a logic circuit to drive the bias lines will be described.
If the polarity switching method by dot inversion is utilized, the polarities of the voltages Vb1 and Vb2 have to be changed with the switching of each frame. In addition, one of the voltages Vb1 and Vb2 may be set to be equal to the voltage V′com. The transistors T3 and T5 may be eliminated if the voltage Vb1 is equal to V′com, and the transistors T4 and T6 may be eliminated if the voltage Vb2 is equal to V′com.
If the polarity switching method by dot inversion is utilized, the polarities of the voltages Vb1 and Vb2 have to be switched with the switching of each frame. The polarity of Vb1 in the previous frame time period f0 is different from that of Vb1 in the first frame time period f1; and the polarity of Vb2 in the previous frame time period f0 is different from that of Vb2 in the first frame time period f1. In addition, one of the voltages Vb1 and Vb2 may be set to be equal to the voltage Vcom. If the voltage Vb1 is equal to Vcom, the transistor T1 and the capacitor C1 may be eliminated; and if the voltage Vb2 is equal to Vcom, the transistor T2 and the capacitor C2 can be eliminated.
If the polarity switching method by dot inversion is utilized, the polarities of the voltages Vb1 and Vb2 have to be changed with the switching of each frame. The polarity of Vb1 in the previous frame time period f0 is different from that of Vb1 in the first frame time period f1. The polarity of Vb2 in the previous frame time period f0 is different from that of Vb2 in the first frame time period f1. In addition, one of the voltages Vb1 and Vb2 may be set to be equal to the voltage V′com. If the voltage Vb1 is equal to V′com, the transistors T2 and T4 may be eliminated. If the voltage Vb2 is equal to V′com, the transistors T1 and T3 may be eliminated.
If the polarity switching method by the dot inversion is utilized, the polarities of the voltages Vb1 and Vb2 have to be switched with the switching of each frame. In addition, one of the voltages Vb1 and Vb2 may be set to be equal to the voltage V′com. If the voltage Vb1 is equal to V′com, the transistors T1 and T3 may be eliminated and B1(n) is directly coupled to V′com. If the voltage Vb2 is equal to Vcom′, the transistors T2 and T4 may be eliminated, and B2(n) is directly coupled to V′com.
Pixel Layout
The first and second embodiments divide one pixel into a first sub-pixel Pa and a second sub-pixel Pb, and the layouts of the first sub-pixel Pa and the second sub-pixel Pb may have any arbitrary shape. Some examples will be described in the following.
Pixel Structure
The LCD panel 100 of the first embodiment may have several configurations. Four examples will be described in the following.
The LCD panel 400 of the second embodiment may have several structures, and four examples will be illustrated.
The embodiments enable the sub-pixels in one pixel of the multi-domain LCD panel to have the driving voltages, which are slightly different from each other, so as to reduce the color difference and enhance the frame stability and the display quality.
While the invention has been described by way of example and in terms of a limited number of embodiments, it is to be understood that the invention is not limited thereto. On the contrary, the present invention is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.
Number | Date | Country | Kind |
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95101483 A | Jan 2006 | TW | national |
Number | Name | Date | Kind |
---|---|---|---|
6958791 | Shimoshikiryo | Oct 2005 | B2 |
7034789 | Takeuchi et al. | Apr 2006 | B2 |
7050038 | Matsuda et al. | May 2006 | B2 |
20030227429 | Shimoshikiryo | Dec 2003 | A1 |
Number | Date | Country |
---|---|---|
1469175 | Jan 2004 | CN |
200401933 | Jun 1992 | TW |
Number | Date | Country | |
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20070164957 A1 | Jul 2007 | US |