The present invention relates a timing control circuit and a liquid crystal display (LCD) using the timing control circuit.
An LCD has the advantages of portability, low power consumption, and low radiation, and has been widely used in various portable information products such as notebooks, personal digital assistants (PDAs), video cameras and the like. Furthermore, the LCD is considered by many to have the potential to completely replace cathode ray tube (CRT) monitors and televisions.
A typical LCD usually includes an LCD panel, a gate driver for scanning the LCD panel, a timing control circuit for transmitting image data to the data driver, and a data driver for providing gradation voltages to the LCD panel according to the received image data. The LCD panel includes a color filter substrate, a thin film transistor (TFT) array substrate, and a liquid crystal layer sandwiched between the two substrates. When the LCD works, an electric field is applied to the liquid crystal molecules of the liquid crystal layer. At least some of the liquid crystal molecules change their orientations, whereby the liquid crystal layer provides anisotropic transmittance of light therethrough. Thus the amount of the light penetrating the color filter substrate is adjusted by controlling the strength of the electric field. In this way, desired pixel colors are obtained at the color filter substrate, and the arrayed combination of the pixel colors provides an image viewed on a display screen of the LCD.
If motion picture display is conducted on the LCD, problems of poor image quality may occur. For example, the residual image phenomenon may occur because a response speed of the liquid crystal molecules is too slow. In particular, when a gradation variation occurs, the liquid crystal molecules are unable to track the gradation variation within a single frame period and produce a cumulative response during several frame periods. Consequently, considerable research is being conducted with a view to developing various high-speed response liquid crystal materials as a way of overcoming this problem.
Further, the aforementioned problems such as the residual image phenomenon are not caused solely by the response speed of the liquid crystal molecules. For example, when the displayed image is changed in each frame period to display the motion picture, the displayed image of one frame period remains in a viewer's eyes as an afterimage, and this afterimage overlaps with the viewer's perception of the displayed image of the next frame period. This means that from the viewpoint of a user, the image quality of the displayed image is impaired.
In order to overcome this problem, a residual image reducing mode driving method for the LCD has been developed. The residual image reducing driving method includes the following steps: dividing a frame into a first sub-frame and a second sub-frame; a data driver providing gradation voltages corresponding to normal image data to an LCD panel in the first sub-frame; and after about a half of the frame has elapsed, the data driver providing black-inserting voltages corresponding to black image data to the LCD panel in the second sub-frame.
Accordingly, a viewer perceives the black image during the second sub-frame, and an afterimage of the normal image displayed in the first sub-frame is lost from the viewer's perception during the second sub-frame. This means that there is no overlap of an afterimage with a perceived image of the next frame. Thus from the viewpoint of a user, the image quality of the displayed image is clear.
However, when the LCD works in the residual image reducing mode, the timing controlling circuit needs to work at double a normal frequency so as to transmit both the normal image data and the additional black image data to the data driver.
When the LCD works in the normal driving mode, if a data-transmitting rate of the timing control circuit 11 is equal to “D” pixel/sec, a working frequency “Xnormal” of the two RSDS output terminals of the timing control circuit 11 is calculated according to the following first formula (1):
The “Port_number” represents the number of RSDS output terminals of the timing control circuit 11. “S” represents an endurable frequency (maximum normal working frequency) of the data driver that communicates with the timing control circuit 11.
As shown in formula (2), when the LCD works in the residual image reducing mode, the working frequency “Xblack-inserting” of the timing control circuit 11 goes beyond the endurable frequency of the data driver. However, the data driver does not operate properly in a double frequency working condition. Therefore, the LCD needs one or more additional data drivers to deal with the additional black image data. Thus the cost of the LCD is increased.
What is needed, therefore, is an LCD that can overcome the above-described deficiencies.
In one preferred embodiment, an LCD includes an LCD panel, a timing control circuit, a plurality of gate drivers connected to the LCD panel, and a plurality of data drivers connected to the LCD panel. The timing control circuit includes a plurality of reduced swing differential signaling (RSDS) output terminals. Each data driver is electrically connected to a respective RSDS output terminal of the timing control circuit via an independent conducting line.
Other advantages and novel features will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
When the LCD having the timing control circuit 12 works in a residual image reducing mode, the LVDS input terminals of the timing control circuit 12 need to receive normal image data and black image data. If the amount of additional black image data is equal to the amount of normal image data, and both of these amounts are equal to “D”, a working frequency Xblack-inserting of the four RSDS output terminals of the timing control circuit 12 is calculated according to the following third formula (3):
The “Port_number” represents the number of RSDS output terminals of the timing control circuit 12. “S” represents an endurable frequency (maximum normal working frequency) of any one of the data drivers that communicates with the timing control circuit 11. That is, when the timing control circuit 12 is used in an LCD that works in the residual image reducing mode, the working frequency of the RSDS output terminals can remain in the range from 0-S. Thus the number of data drivers that communicate with the timing control circuit 12 and that provide the gradation voltages and black-inserting voltages to the LCD panel need not be increased.
Because the LCD 20 includes the timing control circuit 21 having the four RSDS output terminals, the working frequency of the RSDS output terminals can be controlled to be less than that of the data drivers 22. Therefore the number of data drivers 22 that communicate with the timing control circuit 21 and that provide the gradation voltages and black-inserting voltages to the LCD panel 24 need not be increased. Thus the LCD is cost-effective.
In an alternative embodiment of the present invention, another timing control circuit used in an LCD that has a plurality of data drivers 22 is provided. The time control circuit includes a number p (where p is a natural number) of RSDS output terminals, each of which is electrically connected to a respective data driver 22 via an independent conducting line.
If the amount of additional black image data is equal to “M”, and the amount of normal image data is equal to “N”, a working frequency Xblack-inserting of the plurality of RSDS output terminals of the timing control circuit is calculated according to the following fourth formula (4):
The “Port_number” represents the number of RSDS output terminals of the timing control circuit. “S” represents an endurable frequency of the data drivers 22 that communicate with the timing control circuit. The working frequency of the RSDS output terminals can be controlled to be less than that of the data drivers 22.
It is to be understood, however, that even though numerous characteristics and advantages of the present embodiments have been set out in the foregoing description, together with details of the structures and functions of the embodiments, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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