This invention relates to a driving method for a liquid crystal displayer, and particularly to a driving method for a driver integrated circuit.
Currently, thin film transistor liquid crystal displayers (TFT-LCD) are gaining higher occupancy in the market of flat panel displayers. The TFT-LCDs are developing to have large size, multiple color numbers and high resolution.
A Driver integrated circuit (Driver IC) in the existing TFT-LCD only provides same output modes regardless reversion of polarity. Since delay degree of waveforms output by the driver integrated circuit under the same polarity is different from that of waveforms output by the driver integrated circuits after the polarity is inverted, a dim line phenomenon would occur.
An object of the present invention is to provide a driving method for a driver IC, wherein different driving modes are employed according to a condition that a polarity of the driver IC changes to overcome a dim line phenomenon effectively and to improve picture display quality of a liquid display apparatus.
To achieve above object, the present invention provides a driving method for a driver IC, comprising: detecting a polarity of a gate line being driven; when the polarity changes, the driver integrated circuit drives the gate line with a first mode signal; when the polarity does not change, the driver integrated circuit drives the gate line with a second mode signal, a driving current of the first mode signal is greater than that of the second mode signal.
The driving current of the first mode signal is 1.5-3.5 times of that of the second mode signal, preferably, the driving current of the first mode signal is 2.5 times of that of the second mode signal. Further, the first mode signal is a large power mode signal, and the second mode signal is a normal mode signal.
Based on the above solution, the detecting a polarity of a gate line being driven is in detail that: at a driving time of the driver integrated circuit, a timing controller determines whether the polarity of the gate line being driven changes.
Based on the above solution, the detecting a polarity of a gate line being driven is in detail that: at a driving time of the driver integrated circuit, the driver integrated circuit determines whether the polarity of the gate line being driven changes.
The present invention sets forth a driving method for a driver IC, wherein the driver IC drives a gate line in different driving modes according to a condition that a polarity of the droved gate line changes. In particular, at a driving time of the driver IC, when the polarity of the gate line being driven changes, the driver IC drives the gate line with a first mode signal; and when the polarity of the gate line being driven does not change, the driver IC drives the gate line with a second mode signal. Since a driving current of the first mode signal is greater than that of the second mode signal, the present invention is enabled to minimize a difference between charging delays of pixel electrodes on two adjacent gate lines when driving using a two point inverting method, improving a dim line phenomenon. The charging delay of the pixel electrode on the gate line when a polarity of a gate line changes is greater than that when the polarity does not change. Therefore, when the driver IC drives the gate line with the first mode signal with a greater driving current, it is advantageous to reduce the charging delay of pixel electrode on the gate line; and when the driver IC drives the gate line whose polarity does not change with the second mode signal with a smaller driving current, it is advantageous to increase the charging delay of pixel electrode on the gate line, thereby maximally reducing the difference between the charging delays of the pixel electrodes on two gate lines, minimizing a difference between the output waveforms of the pixel electrodes on the two gate lines and improving the dim line phenomenon. Meanwhile, compared with the prior art all driving by employing the large power mode signal, the present invention employs ½ driving area with the large power mode signal and ½ driving area with the normal mode signal, reducing the operation power. Further, in a case that an increase in a size of a panel results in an increase in a load of the panel, the dim line problem due to this can also be solved by the solution of the present invention.
A further detailed description will be made below to the technical solution of the present invention by the accompanying drawings and embodiments.
a,
A driving method for a driver IC of the present invention comprises in detail: monitoring a polarity of a gate line being driven; when the polarity changes, the driver IC drives the gate line with a first mode signal; when the polarity does not change, the driver IC drives the gate line with a second mode signal, a driving current of the first mode signal is greater than that of the second mode signal.
The present invention breaks through a manner that a prior art driver IC uses a single driving mode to drive all gate lines, and sets forth a technical solution of using two driving mode to drive gate lines according to a condition that a polarity of the driven gate line changes. In particular, at a driving time of the driver IC, when a polarity of the driven gate line changes, the driver IC drives the gate line with a first mode signal, and when the polarity of the driven gate line does not change, the driver IC drives the gate line with a second mode signal. Since a driving current of the first mode signal is greater than that of the second mode signal, it enables the present invention to minimize a difference between charging delay of pixel electrodes on two adjacent gate lines when using a two point inverting method driving, and a dim line phenomenon is improved. When a polarity of a gate line changes, a charging delays of a pixel electrode on the gate line is greater than that on the gate line when the polarity dos not change, therefore, when the driver IC drives the gate line with the first mode signal having a greater driving current, it is advantageous to reduce the charging delay of the pixel electrode on the gate line; whereas, when the driver IC drives the gate line whose polarity does not change with the second mode signal having a smaller driving current, it is advantageous to increase the charging delay of the pixel electrode on the gate line, thereby maximally reducing a difference between the charging delays of the pixel electrodes on the two gate lines, minimizing a difference between the output waveforms of the pixel electrodes on the two gate lines and improving the dim line phenomenon.
In the above solution of the present invention, the driving current of the first mode signal may be 1.5-3.5 times of that of the second mode signal. Through adjustment of a driving current ratio of the two driving mode, the difference in the charging delays of the pixel electrodes on the two gate lines may be adjusted to minimize the difference between the output waveforms of the pixel electrodes on the two rows; preferably, the driving current of the first mode signal is 2.5 times of that of the second mode signal. Further, a large power mode signal (heavy mode) or a normal mode signal (normal mode) is set in the output of the existing driver IC. If a load of a panel is greater, the output of the driver IC is set to the large power mode signal; and if the load of the panel is smaller, the output of the driver IC is set to the normal mode signal. With the existing driving mode signals in the prior art, the first mode signal of the present invention can take the large power mode signal directly, and the second mode signal can take the normal mode signal directly, thereby simplifying a control manner and utilizing existing control resources fully.
Based on the above technical solution, the present invention driving gate lines in two driving modes can be implemented in many ways, and will be further described by detailed embodiments.
At step 11, at a driving time of the driver IC, a timing controller determines whether a polarity of a gate line being driven changes, if the polarity changes, then step 12 is performed, and if the polarity does not change, then step 13 is performed;
At step 12, the timing controller sends a first mode signal to the driver IC, thereby the driver IC drives the gate line with the first mode signal;
At step 13, the timing controller sends a second mode signal to the driver IC, thereby the driver IC drives the gate line with the second mode signal.
In this embodiment, the first mode signal and the second mode signal may be a high level and a low level respectively, and also may be a low level and a high level respectively, which are set according to an actual situation. The first mode signal can take a large power mode signal and the second mode signal can take a normal mode signal. The driver IC operates with the large power mode signal when a control pin is a high level, and operates with the normal mode signal when the control pin is a low level.
Since there is a difference between a output slew rate at the time that the polarity changes and the output slew rate at the time that the polarity does not change, charging delays of pixel electrodes on the gate line in the n-th row is greater than that of pixel electrodes on the gate line in the (n+1)-th row. Thus, when the driver IC drivers the gate line in the n-th row with the large power mode signal HM, it is advantageous to reduce the charging delay of the pixel electrode on the gate line in the n-th row, and when the driver IC drivers the gate line in the (n+1)-th row with the normal mode signal NM, it is advantageous to increase the charging delay of the pixel electrode on the gate line in the (n+1)-th row, thereby maximally reducing the difference between the charging delays of the pixel electrodes on the two gate lines, minimizing the difference between the output waveforms of the pixel electrodes on the two gate lines and improving the dim line phenomenon. Compared with the prior art all driving by employing the large power mode signal, the present invention employs ½ driving area with the large power mode signal and ½ driving area with the normal mode signal, reducing the operation power.
At step 21, at a driving time of the driver IC, the driver IC determines whether a polarity of a gate line being driven changes, if the polarity changes, then step 21 is performed, and if the polarity does not change, then step 23 is performed;
At step 22, the driver IC drives the gate line with a first mode signal;
At step 23, the driver IC drives the gate line with a second mode signal.
Compared with the first embodiment shown in
It can be understood by those ordinary skilled in the art that all or part of the steps to achieve the above method embodiments can be implemented by hardware related to program instructions, and the foregoing program can be stored in a computer readable storage medium, and when the foregoing program is executed, the steps including the above methods embodiments will be performed; and the foregoing storage medium includes various media such as ROM, RAM, magnetic disk or optical disk etc. that can store program codes.
Finally, it should be noted that the above embodiments are only used to describe but not to limit the technical solution of the present invention. Although detailed descriptions have been made referring to the preferred embodiments, it should be understood by those ordinary skilled in the art that modifications and equivalent alternations can be made to the technical solution of the present invention without departing from the spirit and the scope of the technical solution of the present invention.
Number | Date | Country | Kind |
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200710175202.X | Sep 2007 | CN | national |