JPS6230405B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for driving a cholesteric nematic phase change type matrix display liquid crystal panel which is subjected to vertical alignment treatment and can be driven at a low voltage.

Cholesterol ice cream with vertical alignment treatment
A matrix display liquid crystal panel that uses a nematic phase transition type electro-optic effect has the following advantages compared to a matrix display liquid crystal panel that uses a field effect-twisted nematic type electro-optic effect: It is excellent because 2) it can have a large number of scanning electrodes, and (3) it has good viewing angle characteristics. The electro-optic effect of the cholesteric-nematic phase transition type mentioned above will be explained. Figure 1 shows the voltage-transmitted light intensity static characteristics of this type. In state 1, the liquid crystal molecules form a spiral domain, and in states 2 and 4, the liquid crystal molecules form a focal domain.
With Konik orientation, the states of 3-1 and 3-2 are
Liquid crystal molecules are oriented perpendicular to the electrode plane.
In FIG. 1, the voltage _YN is the threshold voltage at which the liquid crystal undergoes a phase transition from the cholesteric phase to the nematic phase. 1
State 4 and state 4 are states in which displays are accumulated, but the case where the accumulation state is changed from state 1 to state 4 or from state 4 to state 1 will be described. By applying a voltage higher than V _H to the liquid crystal molecules,
Transition from state 1 or 4 to state 3-1. In the state of 3-1, if the voltage applied to the liquid crystal molecules is set to 0 for a few msec. to 10-odd msec. and then the voltage V is applied, the state of 3-1 will quickly transition to the state of 2. do. On the other hand, if the voltage is reduced to V in state 3-1, the state will pass through state 3-2 and then shift to state 2. However, if V/V _N ≧0.7, 3-2 will continue for a long time (several seconds). remain in the state of If the voltage is changed from V to 0 in state 3-2 and state 2, the voltage shifts to state 1 and 4, respectively, and is accumulated.

A conventional driving method will be described below. In matrix display, a group of column electrodes and a group of row electrodes intersect and a voltage is applied to liquid crystal molecules at the intersection to display a dot-like image. When the row electrode group is line-sequentially scanned, the phase of the voltage applied to the column electrode group is changed depending on whether display dots on the row electrodes are accumulated in the 1 state or the 4 state during scanning. First, in order to erase the display accumulated in state 1 or state 4, alternating current pulse voltages with a peak value V duty of 1 are applied to the row electrode group and the column electrode group, respectively, so that the phases are opposite to each other. . An AC pulse voltage with a peak value of 2V and a duty of 1 is applied to all display dots, and by setting 2V≧ _VH , 3V is applied.
- Transition to state 1. Writing of the display starts in the state 3-1, and the voltage for this writing is shown in FIG. In FIG. 2, 5-s indicates an AC pulse voltage of peak value V duty 1 applied to the row electrode during scanning, and 5-ns indicates voltage 0 applied to the row electrode during non-scanning. The scanning time for each row electrode is several msec to 10-odd msec. 6-s is the display dot on the row electrode during scanning, and the peak value V duty 1 is applied to the column electrode group to make the state 2.
An AC pulse voltage of 6-ns is applied to the display dots on the row electrodes during scanning, in order to maintain the state of 3-2 until the writing of all display dots is completed.
It shows an AC pulse voltage with a peak value V duty 1 applied to the column electrodes. While writing the display, voltage 7 is applied to the selected display dots (dots accumulated in state 4) during scanning, and voltage 9-1 or 9-2 is applied during non-scanning. To non-selected display dots (dots accumulated in a state of 1), voltage 8 is applied during scanning, and voltage 9-1 or 9-2 is applied during non-scanning. After writing is completed, when the voltage applied to the row electrode group and the column electrode group is set to 0, the display dots shift to the 4 or 1 state and are accumulated. The peak value V is determined by the need to maintain the unselected display dot in the 3-2 state during the display writing time and to prevent the 2 state from approaching the 3-1 state.
It is set as 0.7≦V/V _H ≦0.85. Although the conventional driving method has been described above, it is desirable to keep the voltage V as low as possible from the viewpoint of driving circuit design and miniaturization of the power supply. However, V _H
is determined by the liquid crystal material of the liquid crystal panel and the thickness of the liquid crystal layer, so there is a limit to how low the voltage V can be.

An object of the present invention is to provide a method for driving a matrix display liquid crystal panel that can be driven at a lower voltage than conventional driving methods.

Cholesterol ice cream with vertical alignment treatment
In a method of driving a nematic phase transition type matrix display liquid crystal panel by line sequential scanning, a first rectangular wave is applied to the row electrodes during scanning, and a wave height value of the first rectangular wave is applied to the row electrode group during non-scanning. are the same,
A second rectangular wave with three times the frequency is applied to the column electrode group, and when the intersection with the row electrode during scanning is a selected dot, the first rectangular wave is applied;
The present invention is characterized in that a third rectangular wave whose phase is shifted by 2/3π with respect to the first rectangular wave is applied.

Hereinafter, the present invention will be explained in detail using Examples.

As an example for explaining the present invention, a driving method using AC pulse voltage will be described. First, 1
In order to erase the display accumulated in the state or state 4, AC pulse voltages of peak value V ₁ and day 1 are applied to the row electrode group and the column electrode group, respectively, in opposite phases to each other, as in the conventional driving method. Apply the voltage as desired. Since an AC pulse voltage with a peak value of 2V ₁ and a date of 1 is applied to all display dots, 2V ₁ ≧V
By setting it to _H , the liquid crystal molecules of each display dot are in a 3-1 state. Display writing starts in the state 3-1, which will be explained using FIG.
10-s and 10-ns indicate the peak value V ₁ and data 1 AC pulse voltage applied to the row electrodes that are line-sequentially scanned, but 10-s is the voltage that is applied to the row electrodes during scanning. 10-ns is applied to the row electrodes during non-scanning. 10-s
and 10-ns have a phase relationship as shown in the figure, and 10-ns has a frequency three times that of 10-s. 11-s and 11-ns indicate AC pulse voltages of peak value V ₁ and duty 1 applied to the column electrodes, but 11-s is in the same phase as 10-s, and 11-ns is 10-ns. -The 2/3π phase is leading with respect to s. 11-s is the voltage applied to the column electrodes when the display dots where the row electrodes and column electrodes intersect during scanning are shifted to state 2;
ns is the voltage applied to the column electrode when display dots where the row electrode and column electrode intersect during scanning are kept in the 3-2 state until writing of all display dots is completed. 12, 13, 14-1, 14-2
indicates the voltage applied to each display dot, but when the display dot is a selected display dot, this display dot has 12 voltages when scanning, that is, the voltage is 0 volts during scanning, and when not scanning, A voltage of 14-1 or 14-2 is applied. When the display dot is a non-selected display dot, this display dot is applied with a voltage of 13 during scanning, that is, an AC pulse voltage with a peak value of 2V ₁ and a duty of 2/3 (effective value √83).
V ₁ ) is applied, and the voltage 14-1 or 14-2 is applied during non-scanning. 14-1 or 14-2 has a peak value of 2V ₁ and a duty of 2/3.
are AC pulse voltages, but the effective value of these voltages is √83V ₁ . The voltage value applied to the selection display dot is √83V ₁ during non-scanning, but becomes 0 during scanning, so if the scanning time per dot is set to several msec to 10-odd msec as described above, The liquid crystal molecules of the selected display dot are in the 2 state. The voltage value applied to the unselected display dot is √
83V ₁ , the liquid crystal molecules of the non-selected display dots are kept in the 3-2 state. After writing is completed, the voltage applied to the row electrode group and column electrode group is set to 0.
Then, each display dot moves from state 2 to state 4, or from state 3-2 to state 1, and the display is accumulated. Above, using examples,
As described above, according to the present invention, the voltage value applied to each display dot during non-scanning is √
It is 83V ₁ . As mentioned above, in order to maintain the liquid crystal molecules of non-selected display dots in the 3-2 state until the end of writing, 0.7≦√83V ₁ /V _H ≦0.85.
Set V ₁ . Based on the above-mentioned relational expression 2V ₁ >V _H , V ₁ is determined to be 0.5≦V ₁ /V _H ≦0.52. According to the conventional driving method, the voltage value V is 0.7≦V/V _H ≦
Since it was 0.85, according to the driving method of the present invention,
The voltage can be lowered by about 30-38%.

The present invention has been explained in detail using examples above, but the voltages of 10-s, 10-ns, and
11-s and 11-ns are merely examples and do not limit the scope of the claims of the present invention. For example, even if DC pulse voltage is used, 12, 13, 14-1, 1
It is possible to apply a voltage of 4-2 to each display dot.

[Brief explanation of the drawing]

Figure 1 shows the voltage-transmitted light intensity characteristics for explaining the electro-optical characteristics of a cholesteric-nematic phase change type liquid crystal panel, Figure 2 shows the voltage generated by the conventional driving method, and Figure 3 shows the voltage generated by the conventional driving method. FIG. 3 is a diagram showing voltages generated by a driving method according to an embodiment for explaining the invention. 7, 8, 12, 13 are voltages applied to the display dots during scanning, 9-1, 9-2, 14-1, 1
4-2 is the voltage applied to the display dots during non-scanning.

Claims (1)

[Claims] 1. In a method of driving a cholesteric nematic phase change matrix display liquid crystal panel subjected to vertical alignment treatment by line sequential scanning, a first rectangular wave is applied to the row electrodes during scanning, and the row electrode group during non-scanning is A second rectangular wave having the same peak value and three times the frequency as the first rectangular wave is applied to the column electrode group, and when the intersection with the row electrode during scanning is a selected dot, A method for driving a matrix display liquid crystal panel, characterized in that when the first rectangular wave is a non-selected dot, a third rectangular wave whose phase is shifted by 2/3π with respect to the first rectangular wave is applied. .