1. Field of the Invention
The present invention relates to a driving method of an active matrix liquid crystal display panel, and particularly to a method for driving an active matrix liquid crystal display panel that can provide displaying of clear images.
2. General Background
Liquid crystal display (LCD) panels that are lightweight, thin and portable are widely used in consumer products such as LCD-TVs, notebooks, desktop computers, mobile phones and personal digital assistants (PDAs). The application of LCD panels in the market is becoming more and more important. However, liquid crystal molecules used in LCD panels are sticky. This means that the response time of the liquid crystal molecules of an LCD panel is far inferior to that of an electron gun in a conventional cathode ray tube (CRT) display. In addition to switching the active switching elements, the response time of an LCD panel must generally be shorter than 16.7 ms (milliseconds). Otherwise, the quality of a motion picture displayed by the LCD panel and viewed by the human eye may be very poor.
Reference is made to
During the first frame, e.g. a period between t1 and t3, a gate electrode driving device (not shown) supplies a scanning voltage Vg to drive the gate electrode 1040 of the TFT 104. After the TFT 104 is turned on, a source electrode driving device (not shown) supplies a gray scale voltage Vd to the pixel electrode 103 through the source electrode 1041 and the drain electrode 1042 of the TFT 104. Thereby, the pixel electrode 103 is charged to a voltage Vp1 while the gray scale voltage Vd is maintained. When t is equal to t2, the TFT 104 is turned off by turning off the supply of the scanning voltage Vg, whereupon the capacitor 107 maintains the voltage Vp1 until the TFT 104 is turned on at t=t3.
Similarly, during the second frame, when t is equal to t3, the scanning voltage Vg is supplied to drive the TFT 104. The pixel electrode 103 is charged to a voltage Vp2 while the gray scale voltage Vd is maintained. At t=t4, the TFT 104 is turned off by turning off the supply of the scanning voltage Vg, whereupon the capacitor 107 maintains the voltage Vp2.
Because liquid crystal molecules used in the active matrix liquid crystal display panel 100 are sticky, the pixel electrode 103 cannot be charged to the required gray voltage within one frame period of 16.7 ms, and the liquid crystal molecules do not complete their transition to the new alignment in time. As a result, an afterimage of this current frame is perceived on the retina of a viewer's eye, so that the viewer's perception of the image of the next frame will be affected by the afterimage of the current frame. Thus the active matrix liquid crystal display panel 100 fails to provide clear images.
U.S. Pat. No. 5,495,265 entitled “Fast response electro-optic display device” discloses a conventional overdrive method to overcome blurred images. The method relates to an inter-gray response and a look-up table. Data of the look-up table is an overdrive voltage applied to the pixel electrode in order to reduce the response time of the liquid crystal molecules. The overdrive gray-scale voltage is dependent on the previous frame gray scale and subsequent frame gray scale, so that it takes less than 16.7 ms to change the brightness of the pixels between different gray scales. When the levels of gray scales are increased, the data is interpolated by the gray-scale voltages between the previous frame and the subsequent frame of the look-up table. The number of data is increased in geometric series. For example, if the level of gray scale is 8 digits, the size of the look-up table used to store these data should have 8×8=64 digits. That is, the higher the number of gray scales, the larger the size of the look-up table. If the size of the look-up table is increased, the cost of the device is also higher. In some cases, a smaller-sized look-up table can be used, or associated hardware can be implemented to replace the look-up table. However, with these alternative configurations, the performance of the device is not optimal.
Therefore, there is a need for a method for driving an active matrix liquid crystal display panel that can display clear images efficiently.
A method for driving an active matrix liquid crystal display panel that can display clear images is provided.
Dada signals are supplied to a plurality of pixel electrodes of the liquid crystal display panel so that corresponding pixels display images. The steps of the driving method are as follows. First, a frame period is divided into a display period and a black insertion period. A gray-scale voltage is generated so that a corresponding light transmittance of each pixel is determined; and during the display period, the gray-scale voltage is supplied to the corresponding pixel electrode of the liquid crystal display panel. Then, during the black insertion period, a restore voltage is supplied to the pixel electrode so that the state of the pixel is returned to an initial black state.
Unlike in the prior art, the above-described method supplies the restore voltage to the pixel electrode so that the pixel is returned to the black state before the subsequent frame period begins. Thus the pixel is in the black state before the pixel displays an image corresponding to the subsequent frame period. Accordingly, from a viewer's perception, the image of the previous frame period has no adverse impact on the image of the subsequent frame period. That is, images displayed by the liquid crystal display panel are clear and smooth.
Other advantages and novel features of embodiments of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings, in which:
The following detailed description is of the best presently contemplated modes of carrying out the invention. This description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating general principles of embodiments. The scope is defined by the appended claims and equivalents thereof.
During a display period (ti) of the first frame period, a gate electrode driving device (not shown) supplies a scan voltage Vg to drive the gate electrode 2040 of the TFT 204 at time t1. Thereby, the TFT 204 is turned on. In addition, a source electrode driving device (not shown) supplies a gray-scale voltage Vs1 to the pixel electrode 203 through the source electrode 2041 and the drain electrode 2042. The pixel electrode 203 is charged to a voltage Vp1 because of the gray-scale voltage Vs1 supplied. When the scan voltage Vg is turned off to turn off the TFT 204 at time t2, the capacitor 207 maintains the voltage Vp1 of the pixel electrode 203. During a black insertion (hereinafter referred to as “BI”) period (tr) of the first frame period, the scan voltage Vg is used to drive the gate electrode 2040 of the TFT 204 so that the TFT 204 is turned on again. In addition, the source electrode driving device supplies a restoring voltage Vh to the pixel electrode 203 through the source electrode 2041 and the drain electrode 2042. The pixel electrode 203 is charged to a restored voltage Vh′ because of the restoring voltage Vh supplied. When the scan voltage Vg is turned off to turn off the TFT 204 at time t2′, the capacitor 207 maintains the restored voltage Vh′. Accordingly, the pixel is returned to an initial black state.
Similarly, during the display period (ti, not labeled) of the second frame period (not labeled), the gate electrode driving device supplies a scan voltage Vg to drive the gate electrode 2040 of the TFT 204 at time t3. Thereby, the TFT 204 is turned on. In addition, the source electrode driving device (not shown) supplies a gray-scale voltage Vs2 to the pixel electrode 203 through the source electrode 2041 and the drain electrode 2042. The pixel electrode 203 is charged to a voltage Vp2 because of the gray-scale voltage Vs2 supplied. When the scan voltage Vg is turned off to turn off the TFT 204 at time t4, the capacitor 207 maintains the voltage Vp2 of the pixel electrode 203. During the BI period (tr, not labeled) of the second frame period, the scan voltage Vg is used to drive the gate electrode 2040 of the TFT 204 so that the TFT 204 is turned on again. In addition, the source electrode driving device supplies a restoring voltage Vh to the pixel electrode 203 through the source electrode 2041 and the drain electrode 2042. The pixel electrode 203 is charged to a restored voltage Vh′ because of the restoring voltage Vh supplied. When the scan voltage Vg is turned off to turn off the TFT 204 at time t4′, the capacitor 207 maintains the restored voltage Vh′. Accordingly, the pixel is returned to its initial black state.
Referring to
The steps of the above-described exemplary driving method can be summarized as follows. First, a frame period is divided into a display period ti and a BI period tr. A gray-scale voltage Vs is generated so as to provide a corresponding desired light transmittance of the pixel; and during the display period ti, the gray-scale voltage Vs is supplied to the pixel electrode 203 of the liquid crystal display panel 200. Then during the BI period tr, a restoring voltage Vh is supplied to the pixel electrode 203, so that the pixel is returned to an initial black state.
According to the exemplary driving method, the ratio of the display period ti to the BI period tr can be equal to one (1), more than one, or less than one. The resolution of the gray scale voltage can be 8 levels, 16 levels, 32 levels, or 64 levels. The gray-scale voltage can be obtained from 64-level formats of a transmittance-voltage (T-V) curve.
Furthermore, according to the exemplary driving method, only the response of the gray-scale voltage from the initial black state needs to be measured. That is, only the response of the gray-scale voltage Vs against the pixel electrode needs to be considered. Measurement of the inter-gray response of the gray-scale voltage Vs and a setup of a corresponding look-up table are simplified. Compared with the prior art, the exemplary driving method re-defines the gray-scale voltage Vs. During the BI period, the restoring voltage Vh is supplied to the pixel electrodes of the liquid crystal display panel, so that each pixel is returned to its initial black state before the subsequent frame period begins. At the moment each gray-scale voltage is supplied, liquid crystal molecules of the liquid crystal display panel are oriented in a position corresponding to the black state. That is, before each pixel displays an image, the pixel is in an initial black state. Accordingly, from a viewer's perception, the image of a previous frame period does not have an adverse impact on the image of a subsequent frame period. This means that the quality of motion pictures provided by the liquid crystal display panel is good.
It is to be further understood that even though numerous characteristics and advantages of the embodiments have been set forth in the foregoing description, together with details of the functions of the embodiments, the disclosure is illustrative only, and changes may be made in detail, especially in matters of arrangement of steps to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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