JPH08211408A - Liquid crystal display device and its driving method - Google Patents

Abstract

PURPOSE: To provide a display device which eliminates image sticking and after-images without generating side-effects, such as crosstalks and its driving method. CONSTITUTION: The scanning signal ϕ(n) in this liquid crystal display device and its driving method has a first selection period Ts1(n) and second Ts2(n) and has a first reset period Tr1(n) and second reset period Tr2(n) prior to the selection periods and a first current impression period Ti1(n) and second current impression period Ti2 (n) prior to the reset periods. Then, the scanning signal having the selection periods, the reset periods prior to the selection periods and the current impression periods prior to the reset periods, by which the reduction of stickingss by the simple method without the side-effects, such as crosstalks, is made possible.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION Liquid crystal display devices are widely applied as low power consumption flat panel displays. Among them, the active matrix system in which a switching element is built in each pixel and driven is being used as a large-capacity and high-quality display element in televisions, information terminals, and the like.

Further, a non-linear resistance element such as a three-terminal type thin film transistor (hereinafter referred to as TFT) and a two-terminal type diode or a metal insulator metal (hereinafter referred to as MIM) is used as a switching element.
The terminal type is easier to manufacture than the three-terminal type and is expected in the future. The present invention relates to a two-terminal active matrix liquid crystal display device using a two-terminal switching element and a driving method thereof.

[0003]

2. Description of the Related Art FIG. 3 shows a block diagram of an active matrix liquid crystal display device using a two-terminal type switching element. The matrix display panel 3 has data lines D1 and D
2 ,. ． , DM and scan lines S1, S2 ,. ． , SN are arranged in a matrix, and the liquid crystal pixels 1 and the two-terminal type switching elements 2 are installed corresponding to the intersections.

The data lines D1, D2 ,. ． , DM is supplied with a data signal from the data line driver circuit 4, and scan lines S1, S2 ,. ． , SN is supplied with a scanning signal from the scanning line driver circuit 5, and the data line driver circuit 4 and the scanning line driver circuit 5 are connected to a control circuit and a power supply circuit 6 for processing a clock and a video signal 7.

As the two-terminal type switching element, an MIM element having a metal-insulator-metal (conductor) structure and a non-linear current-voltage characteristic is often used. MI
As a typical structure of the M element, a lower electrode Ta, an anodic oxide film (TaOx) of Ta as an insulating film, and an ITO (transparent conductor) as an upper electrode are provided, and two patterns (masks) are provided.
Can be manufactured in.

Japanese Patent Laid-Open No. 59-57288 discloses an example of using a conventional two-terminal type switching element. FIG. 4 shows a scanning signal waveform and a data signal waveform in a driving method of a conventional two-terminal type active matrix liquid crystal display device such as a diode or MIM.

Scan signals φ (n), φ (n + 1), φ (n
+2) are scanning signals applied to the nth scanning line, the n + 1th scanning line, and the n + 2th scanning line Sn, Sn + 1, Sn + 2, respectively. Negative polarity selection periods S (n) and S '(n
+1) and S (n + 2), the second selection potential Vs2 is changed to the positive selection period S ′ (n), S (n + 1), S ′ (n +
In 2), the first selection potential Vs1 is taken.

On the other hand, holding periods H (n) and H '(n +
1) and H (n + 2) take the second holding potential Vh2, and the holding periods H '(n), H (n + 1), and H' (n + 2) take the first holding potential Vh1.

The data signal D (m) applied to the m-th data line Dm has a potential between the first data potential Vd1 and the second data potential Vd2 as shown in the figure. For the gradation display, either amplitude modulation or pulse width modulation is used, and the latter example is shown in FIG. VG is a reference potential,
In FIG. 4, the potential is drawn at a constant potential, but even if it fluctuates throughout the system, it is in principle equivalent, so it is often varied depending on the relationship of the power supply voltage of the driver circuit.

In FIG. 4, the first selection potential Vs1, the second selection potential Vs2, the first holding potential Vh1 and the second holding potential Vh2 are shown symmetrically with respect to the reference potential, but they are two-terminal type. When the characteristics of the switching element are asymmetric, they may be asymmetric.

Further, in the conventional example shown in FIG. 4, the n-th line, n +
Continuous selection periods S (n), S (n + 1), S (n + 2) corresponding to the first and (n + 2) th scanning lines and selection periods S ′ (n), S ′ (n + 1), S ′ (n + 2) The polarities of the selection potentials of and are inverted, which corresponds to the example of row-by-row inversion.
In many cases, every field is reversed.

The biggest problem in an active matrix liquid crystal display device using a two-terminal type switching element, especially when using MIM as a switching element, is image sticking or an afterimage phenomenon.

FIG. 5 is a diagram for explaining the burning problem of the conventional example. FIG. 5A is a graph showing the state of the transmittance with respect to the ideal time. FIG. 5B is a graph showing the state of transmittance with respect to actual time.

In the case of normally white display, the change in transmittance shown in FIG. 5 (a), that is, in the case of sequentially displaying white, halftone, black, and halftone, the actual change in transmittance is shown in FIG. 5 (b). Therefore, the change in the transmittance of the intended ideal image does not match that in FIG. When the image changes from white to halftone, an image slightly darker than the halftone is burned in for a certain period such as 17, and conversely, when it is changed from black to halftone, an image slightly brighter than the halftone is burned for a certain period such as 18.

This is the threshold voltage Vth of the switching element.
Is due to change. This change depends on the amount of current flowing through the switching element. When the amount of current is large, the threshold voltage Vth tends to increase when the current amount is large, and conversely, the threshold voltage Vth tends to decrease for a small amount of current.

FIG. 6 is a waveform diagram showing a scanning signal waveform and a data signal waveform in a conventional example for reducing burn-in in a driving method of a two-terminal type active matrix liquid crystal display device.

Scan signals φ (n), φ (n + 1), φ (n
+2) are scanning signals applied to the nth scanning line, the n + 1th scanning line, and the n + 2th scanning line Sn, Sn + 1, Sn + 2, respectively. Negative polarity selection periods S (n) and S '(n
+1) and S (n + 2), the second selection potential Vs2 is changed to the positive selection period S ′ (n), S (n + 1), S ′ (n +
In 2), the first selection potential Vs1 is taken.

On the other hand, holding periods H (n) and H '(n +
1) and H (n + 2) take the second holding potential Vh2, and the holding periods H '(n), H (n + 1), and H' (n + 2) take the first holding potential Vh1.

The data signal D (m) applied to the m-th data line Dm takes a potential between the first data potential Vd1 and the second data potential Vd2 as in the conventional example of FIG.

The driving waveform of FIG. 6 is characterized by the scanning signals φ (n), φ (n + 1), and φ (n + 2) having positive polarity selection periods S (n) and S ′ (n + 1), respectively. ),
Before S (n + 2), a negative polarity current application period I (n),
I '(n + 1), I (n + 2), negative selection period S'
Before (n), S (n + 1), S '(n + 2), the positive current application period I' (n), I (n + 1), I '(n +
2).

In the driving method of the conventional example shown in FIG. 6, it is expected that the characteristic change of the element will be saturated and the image sticking will be suppressed by forcing a current to flow through the switching element during this current application period. ing.

[0022]

In the driving method of the conventional example shown in FIG. 4, the amount of current flowing through the switching element varies depending on the gradation displayed on the liquid crystal pixel, and the burn-in phenomenon cannot be eliminated.

On the other hand, in the driving method of FIG. 6, let us consider a case where the area from the scanning line Sn-1 to the scanning line Sn + 2 is white display. In the case of normally white display, since the data potential corresponding to the white display is the data potential having the same polarity as the polarity of the selection potential of the scanning line, the selection period S (n-1),
In S (n), S (n + 1), and S (n + 2), the data signal D (m) has a first data potential Vd1, a second data potential Vd2, a first data potential Vd1, and a second data potential, respectively. Take Vd2.

Similarly, the selection periods S '(n-1), S'.
In (n), S '(n + 1), and S' (n + 2), the data signal D (m) has the second data potential Vd2, the first data potential Vd1, the second data potential Vd2, and the first data potential, respectively. Take Vd1.

That is, in the white display area, the voltage difference between the scanning signal φ (n) and the data signal D (m) corresponding to the voltage applied to the liquid crystal pixel and the switching element in the selection period is Vs2-Vd2. Alternatively, the absolute value becomes Vs1-Vd1.

On the other hand, in the black display region, the voltage difference between the scanning signal φ (n) and the data signal D (m) corresponding to the voltage applied to the liquid crystal pixel and the switching element in the selection period is Vs.
The absolute value increases to 2-Vd1 or Vs1-Vd2.

Further, the scanning signal φ applied to the scanning line Sn
In (n), the selection period S (n
-1), S '(n-1) is the current application period I (n), I'
Used as (n).

Therefore, the scanning signal φ corresponding to the voltage applied to the liquid crystal pixel and the switching element during the current application period.
The voltage difference between (n) and the data signal D (m) is Vs2-Vd.
The absolute value becomes 2 or Vs1-Vd1.

From the same discussion, the voltage difference between the scanning signal φ (n) and the data signal D (m) corresponding to the voltage applied to the liquid crystal pixels and the switching elements in the black display region during the current application period is Vs2-. The absolute value increases to Vd1 or Vs1-Vd2.

As described above, in the white display region, the voltage applied to the liquid crystal pixel and the switching element is small in both the selection period and the current application period, and in the black display region, both the selection period and the current application period are large. Become.

As described above, the driving method of FIG. 6 aims to suppress the burn-in by saturating the characteristic change of the element by forcibly flowing the current in the switching element during the current application period.

However, in this way, in practice, since the same display content dependency as in the selection period remains in the current application period, the characteristic change does not saturate easily and the sufficient effect of reducing the burn-in may not be obtained. There is a problem to do.

In order to improve the above problems, it may be possible to independently set the current application period without using the selection period of another scanning line. Since the data signal during the current application period can be adjusted independently, when the voltage applied to the liquid crystal pixels and the switching elements is small during the selection period as in the white display region, it is large during the current application period and the black display region As described above, when the selection period is large, the current application period can be set to be small.

However, in such a case, the data signals in the current application period and the selection period have the same polarity, and there is a worst pattern in which the polarity of the average value of the data signal is biased depending on the data content. In such a worst case pattern, there is a problem that ugly crosstalk occurs on the screen and the display quality is impaired.

The object of the present invention is to solve the problems of the conventional examples,
An object of the present invention is to provide a liquid crystal display device capable of sufficiently reducing image sticking and suppressing crosstalk, and a driving method thereof.

[0036]

In order to achieve the above object, a liquid crystal display device and a driving method thereof according to the present invention include a plurality of data lines, a plurality of scanning lines, and an intersection of the data lines and the scanning lines. A liquid crystal having a liquid crystal pixel provided correspondingly and a two-terminal switching element provided corresponding to the liquid crystal pixel, and driving the liquid crystal pixel according to a scanning signal applied to the scanning line and a data signal applied to the data line. In the display device, the scan signal has a selection period, a reset period preceding the selection period, and a current application period preceding the reset period.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, A reset period prior to the selection period and a current application period prior to the reset period, and the scanning signal has a polarity opposite to the selection period and a polarity of the current application period prior to the reset period. Has the same polarity as the selection period.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, The scanning signal has a reset period prior to the selection period and a current application period prior to the reset period, and the scanning signal alternately has a positive selection period and a negative selection period.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device having a two-terminal type switching element provided as a drive circuit and driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, the scanning signal has a positive polarity. A selection period of negative polarity and a selection period of negative polarity are alternately provided, and a reset period of negative polarity precedes the selection period of positive polarity and a current application period of positive polarity precedes the reset period of negative polarity. It is characterized in that it has a positive polarity reset period prior to the period and a negative polarity current application period prior to the positive polarity reset period.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device having a two-terminal type switching element provided as a drive circuit and driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, the scanning signal has a positive polarity. A selection period of negative polarity and a selection period of negative polarity are alternately provided, and a reset period of negative polarity precedes the selection period of positive polarity and a current application period of positive polarity precedes the reset period of negative polarity. A positive polarity reset period prior to the period, a negative polarity current application period prior to the positive polarity reset period, and a negative polarity reset potential during a negative polarity reset period prior to the positive selection period of the scan signal, and Negative polarity selection period And the selection potential is the same potential,
The positive polarity reset potential in the positive polarity reset period preceding the negative polarity selection period and the selection potential in the positive polarity selection period are the same potential.

Further, the liquid crystal display device and the driving method thereof according to the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, A reset period preceding the selection period and a current application period preceding the reset period are provided, and the time width of the reset period is shorter than the time width of the selection period.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, It has a reset period prior to the selection period and a current application period prior to the reset period, and the selection potential in the selection period and the current application potential in the current application period are the same potential.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, A reset period preceding the selection period and a current application period prior to the reset period are provided, and the time width of the selection period and the time width of the current application period are equal.

Further, the liquid crystal display device and the driving method thereof of the present invention correspond to a plurality of data lines, a plurality of scanning lines, liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines, and liquid crystal pixels. In a liquid crystal display device that has a two-terminal switching element that is provided for driving liquid crystal pixels according to a scanning signal applied to a scanning line and a data signal applied to a data line, , A reset period prior to the selection period and a current application period prior to the reset period, and the average value of the data potential of the data signal over both the selection period of the scanning signal and the current application period is substantially constant. It is characterized by

[0045]

The scanning signal has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period. Due to the existence of this reset period, the polarity of the current application period can be set to the same polarity as that of the selection period by setting the polarity of the reset period to be opposite to that of the selection period.

When the average value of the data signals in the scanning signal selection period and the current application period is set to a substantially constant value regardless of the image content, crosstalk can be suppressed to a minimum.

When the scanning signal and the data signal are driven as described above, since the selection period of the scanning signal and the current application period have the same polarity, the total sum of the currents applied to the switching elements is almost equal in both periods. The image burn-in can be suppressed regardless of the image content.

As described above, according to the present invention, it is possible to provide a liquid crystal display device in which image sticking is reduced and crosstalk is suppressed, and a driving method thereof.

[0049]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a waveform diagram showing a scanning signal and a data signal in the embodiment of the present invention.

The scanning signals φ (n) and φ (n + 1) are scanning signals applied to the nth and n + 1th scanning lines Sn and Sn + 1, respectively. Each scanning signal has an independent scanning period.

For example, the scanning signal φ (n) is for the first scanning period T1 (n) and the second scanning period T2 (n), and the scanning signal φ (n + 1) is for the first scanning period T1 (n + 1). And the second
Scanning period T2 (n + 1) of each scanning period, and the scanning periods thereof do not overlap each other.

Each scanning period has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period. For example, the first scanning period T1 (n)
And the second scanning period T2 (n) are equal to the first selection period Ts.
1 (n) and the second selection period Ts2 (n), the first reset period Tr1 (n) and the second reset period Tr2 (n) preceding the selection period, and the first reset period Tr2 (n) preceding the reset period.
Current application period Ti1 (n) and second current application period Ti
2 (n).

After each of the first scanning period T1 (n) and the second scanning period T2 (n), there are a first holding period Th1 (n) and a second holding period Th2 (n). Continues.

The scanning signal has the first selection potential Vs1 in the first selection period Ts1 (n) and the second selection period Ts2.
In (n), the second selection potential Vs2 is set, and in the first reset period Tr1 (n), the first reset potential Vr1 is set.
In the second reset period Tr2 (n), the second reset potential Vr2 is set.

In the first current application period Ti1 (n), the first current application potential Vi1 is changed to the second current application period T1.
At i2 (n), the second current applied potential Vi2 is taken and
Of the first holding potential Vh1 during the holding period Th1 (n) of
In the second holding period Th2 (n), the second holding potential Vh2
Take

In the embodiment of the present invention, the first selection potential Vs
1 and the first current application potential Vi1 have the same polarity, and the first selection potential Vs1 and the first reset potential Vr1
Has a polarity opposite to that of the first scanning period T1 (n)
And the second scanning period T2 (n) have opposite polarities.

Comparing the n-th scanning signal φ (n) with the n + 1-th scanning signal φ (n + 1), the adjacent n-th first scanning period T1 (n) and n + 1-th second scanning period The respective potentials of T2 (n + 1) have opposite polarities, and an example of so-called row-by-row inversion is shown. Of course, the present invention is not limited to line-by-line inversion, but is also effective in frame inversion and inline inversion.

In FIG. 1, the data signal is D (m) when the pixel on the n-th row is on, D '(m) when the pixel is in the halftone,
The case of OFF is indicated by D ″ (m).

First, when the pixel in the nth row is on, the corresponding first selection potential Vs in the first selection period Ts1 (n).
Since 1 has a positive polarity, the second data potential Vd having the opposite polarity
2, and the corresponding second selection potential Vs2 has a negative polarity in the second selection period Ts2 (n), the first polarity having the opposite polarity.
Of the data potential Vd1.

The data potentials of the first current application period Ti1 (n) and the second current application period Ti2 (n) are the same as those of the first selection period Ts1 (n) and the second selection period Ts2.
A first data potential Vd having a polarity opposite to that of (n).
1 and the second data potential Vd2.

Further, the first reset period Tr1 (n)
And the data signal of the second reset period Tr2 (n) is
In order to enhance the reset effect, the first reset potential Vr1
And a first data potential Vd1 and a second data potential Vd2, which have opposite polarities to the second reset potential Vr2.

On the other hand, the data signal D ″ (m) when the pixel on the n-th row is off is the same as the data signal D ″ (m) for the first selection period Ts1 (n).
Corresponding to the selection period Ts2 (n) of the first selection potential Vs1 and the second selection potential Vs2 having the same polarity as the first polarity.
Data potential Vd1 and second data potential Vd2.

The data potentials of the first current application period Ti1 (n) and the second current application period Ti2 (n) are the same as those of the first selection period Ts1 (n) and the second selection period Ts2.
A second data potential Vd having a polarity opposite to the data potential of (n)
2 and the first data potential Vd1.

Further, the first reset period Tr1 (n)
And the data signal of the second reset period Tr2 (n) is
In order to enhance the reset effect, the first reset potential Vr1
And a first data potential Vd1 and a second data potential Vd2, which have opposite polarities to the second reset potential Vr2.

Next, the data signal D '(m) in the case where the pixel on the nth row is in the halftone uses a halftone display waveform by so-called PWM (pulse width modulation method), and the first selection period Ts is used.
1 (n) and the second selection period Ts2 (n),
Both the data potential having the same polarity and the data potential having the opposite polarity with respect to the polarities of the first selection potential Vs1 and the second selection potential Vs2 are taken at a ratio corresponding to the gradation.

Further, in the first current application period Ti1 (n) and the second current application period Ti2 (n), the first selection period Ts1 (n) and the second selection period Ts2 (n) are described above. It has the opposite polarity to the data signal. That is, the first data potential Vd1 and the second data potential Vd2 of the data signal in the first selection period Ts1 (n) and the second selection period Ts2 (n) are taken at opposite time ratios.

Furthermore, the first reset period Tr1 (n)
And the data signal of the second reset period Tr2 (n) is
Similar to D (m) and D ″ (m) described above, in order to enhance the reset effect, the first reset potential V
r1 and the first reset potential Vr2 have the opposite polarity
Data potential Vd1 and second data potential Vd2.

FIG. 2 is a diagram showing voltage waveforms applied to the liquid crystal pixels and the switching elements according to the scanning signal and the data signal in the embodiment of the present invention.

FIG. 2 shows voltage waveforms applied to the liquid crystal pixels and the switching elements, which correspond to the ON pixel, the halftone pixel and the OFF pixel, respectively. In the ON pixel, the scanning signal φ (n)- The data signal D (m), the scanning signal φ (n) -data signal D '(m) is applied to the halftone pixel, and the scanning signal φ (n) -data signal D "(m) is applied to the off pixel.

First, the writing operation and the holding operation for the liquid crystal pixels will be described. The write operation is basically centered on the first selection period Ts1 (n) and the second selection period Ts2 (n). In the following description, the data potential Vd =
(First data potential Vd1-Second data potential Vd2)
/ 2.

In the first selection period Ts1 (n), the first selection potential Vs1 + corresponds to ON, halftone, and OFF of the pixel.
Data potential Vd, first selection potential Vs1 ± data potential V
d, the first selection potential Vs1−data potential Vd is applied.

Similarly, in the second selection period Ts2 (n), the second selection potential V corresponds to ON, halftone, and OFF of the pixel.
s2-data potential Vd, second selection potential Vs2 ± data potential Vd, second selection potential Vs2 + data potential Vd are applied.

A voltage obtained by removing the threshold voltage of the switching element and the capacitance couple from these voltages is written in the liquid crystal pixel, and holding periods Th1 (n) and Th2 following the selection period are written.
(N) is held and displayed.

In the selection period, the voltage applied to the liquid crystal pixel and the switching element depends on the display contents (ON-halftone-OFF) of the pixel as described above, and the first data potential V
A difference occurs between d1 and the second data potential Vd2.

However, as it is, the image history occurs because the voltage (current) history of the switching element differs depending on the display content. Therefore, in the present invention, the current application period is provided prior to the selection period in order to improve image sticking. The operation during this current application period will be described below.

As shown in FIG. 2, the first current application period T
In i1 (n), the first current application potential Vi1−data potential Vd, the first current application potential Vi1− ± data potential Vd, the first current application potential Vi1−data potential Vd, the first The current application potential Vi1 + data potential Vd is applied to the liquid crystal pixels and the switching elements.

Here, assuming that the first selection potential Vs1 = the first current application potential Vi1 and the width of the first selection period Ts1 (n) = the width of the first current application period Ti1 (n), the first Selection period Ts1 (n) and first current application period Ti1 (n)
In total, the voltage applied to the liquid crystal pixel and the switching element does not depend on ON, halftone, and OFF of the pixel at all, and the first selection potential Vs1 (Vr1) + data potential Vd In time, the first selection potential Vs1 (V
r1) -Data potential Vd.

The above description applies to the first scanning period T1.
Although the description is for (n), the same applies to the second scanning period T2 (n). As described above, according to the present invention, it is possible to completely compensate for the difference in the applied current depending on the display content during the selection period during the current application period.

In the embodiment of the present invention, the first selection period Ts
1 (n) and the second selection period Ts2 (n) and the first reset period provided between the first current application period Ti1 (n) and the second current application period Ti2 (n) preceding the first selection period Ts2 (n). T
It is characterized by r1 (n) and the second reset period Tr2 (n).

The polarity of the reset period is opposite to that of the selection period, and the polarity of the current application period preceding the reset period is the same as the polarity of the previous selection period. This reset period is provided to make the voltage polarities of the selection period and the current application period uniform.

For example, in the first selection period Ts1 (n),
When the first selection potential Vs1 has a positive polarity, the first reset period Tr1 having the negative first reset potential Vr1
By providing (n), the first reset period Tr1
The first of the first current application period Ti1 (n) prior to (n)
It is possible to make the current application potential Vi1 of the same polarity as that of the first selection potential Vs1.

In the embodiment of the present invention, the scanning signal alternately has a positive selection period and a negative selection period, has a reset period before each selection period, and has a current before the reset period. It is characterized by having an application period.

More specifically, the scan signal alternately has a positive polarity selection period and a negative polarity selection period, and a negative polarity reset period prior to the positive polarity selection period and a positive polarity prior to the negative polarity reset period. A positive polarity reset period prior to the negative polarity selection period, and a negative polarity current application period prior to the positive polarity reset period.

Similar to the first reset period described above, the second reset period Tr2 (n) is also the second current application period Ti2.
In order to align the polarity of the second current application potential Vi2 of (n) with the second selection period Ts2 (n), the second reset potential Vr2 having the opposite polarity to the second selection potential Vs2 is used.

In the embodiment of the present invention, the introduction of the reset period makes it possible to make the scanning signal polarities of the current application period and the selection period uniform, and as a result, the data potential of the data signal over both the selection period and the current application period. It is possible to make the average value of a substantially constant value.

That is, the data signal D (m) of FIG.
In D ′ (m) and D ″ (m), the first current application period Ti1 (n) and the first selection period Ts1 (n) regardless of whether the display content of the corresponding pixel is on, halftone, or off. The average value of the data signals of and is always zero.

Further, the data signals D (m), D '(m),
The average value of the data signal of the second current application period Ti2 (n) of D ″ (m) and the second selection period Ts2 (n) also depends on whether the display content of the corresponding pixel is on, halftone, or off. As a result, the crosstalk depending on the display content of the pixel can be almost completely suppressed.

In the embodiment of the present invention, for example, the selection period, the reset period preceding the selection period, and the current application period preceding the reset period are continuous, respectively, but a period during which a little current does not flow may be provided therebetween. I don't care. Similarly, the holding period does not have to be continuous as long as it is after the selection period.

In the embodiment of the present invention, the data signals D (m), D '(m), D "applied to the m-th data line.
As in the conventional example of FIG. 4, (m) has a potential between the first data potential Vd1 and the second data potential Vd2 as in the conventional example of FIG.

Therefore, for gradation display, either amplitude modulation or pulse width modulation is used, and the latter example is shown in FIG. 1, but of course amplitude modulation may be used. Further, some frame modulation may be used together, or dither gradation for each pixel may be used together.

In the embodiment of the present invention shown in FIG. 1, scanning signals φ (n), φ (n + 1), data signals D (m), D '.
(M) and D ″ (m) are described with reference to the reference potential indicated by the alternate long and short dash line. Although the reference potential is drawn as a constant potential in FIG. 1, the reference potential may be changed.

By changing the reference potential, it is possible to save the withstand voltage of the drive IC, and although the drive waveforms seem to be different, they are completely equivalent. The present invention is effective for such a variable power supply method or a fixed power supply method.

Further, in FIG. 1, the first selection potential Vs1 and the second selection potential Vs2, the first reset potential Vr1 and the second selection potential Vs1
Reset potential Vr2, first current application potential Vi1 and second current application potential Vi2, first holding potential Vh1 and second
The holding potential Vh2 and the first data potential Vd1 and the second data potential Vd2 are shown symmetrically with respect to the reference potential, but they may be asymmetrical. Further, although this example corresponds to an example of line-by-line inversion, field inversion or inline inversion may be performed.

In the embodiment of the present invention, the first selection period Ts
The first reset potential Vr1 and the second selection period Ts2 of the first reset period Tr1 (n) prior to 1 (n)
The second selection potential Vs2 of (n) is described as the same negative potential.

Further, the second reset potential Vr2 in the second reset period Tr2 (n) preceding the second selection period Ts2 (n) and the first selection potential Vs1 in the first selection period Ts1 (n) are set. Are described as the same positive potential.

In the present invention, it is not always necessary to commonly use these potentials, but since the above potentials sufficiently function at the same potential, they can be shared, and in that case, in terms of saving the number of power supplies in the circuit. It has great merit.

In the embodiment of the present invention, the time width of the reset period is set shorter than the time width of the selection period. That is, the time width of the first reset period Tr1 (n) is shorter than the time width of the first selection period Ts1 (n), and similarly,
The time width of the reset period Tr2 (n) is shorter than the time width of the second selection period Ts2 (n).

The scanning period assigned to each scanning signal is finite, and in order to effectively use this limited scanning period, a longer time is required between the current application period and the selection period than the reset period. The allocation is more advantageous in terms of display performance such as drive capacity and, in turn, contrast. The reset period of the present invention can be set shorter than the selection period because the purpose is only to reset the charges injected in the current application period. In the embodiment of the present invention, the reset period has a time width of the selection period. It is set shorter than the time width of.

In the embodiment of the present invention, the same potential is used as the selection potential in the selection period and the current application potential in the current application period.

That is, the first selection potential Vs1 in the first selection period Ts1 (n) and the first selection period Ts1
The first of the first current application period Ti1 (n) prior to (n)
The current applied potential Vi1 of 1 is described as the same positive potential.

In the second selection period Ts2 (n), the second selection period Ts2 (n)
Selection potential Vs2 and the second current application potential Vi2 in the second current application period Ti2 (n) preceding the second selection period Ts2 (n) are described as the same negative potential. .

In the embodiment of the present invention, the time width of the selection period and the time width of the current application period are set equal. That is, the time width of the first selection period Ts1 (n) of the scan signal and the first current application period Ti1 preceding the first selection period.
The time width with (n) is equal.

Similarly, the time width of the second selection period Ts2 (n) and the second current application period T preceding the second selection period Ts2 (n).
The time width of i2 (n) is also equal. In the present invention, as described with reference to FIG. 2, the optimum condition is that the total voltages in the selection period and the reset period are equal, and the optimum condition is satisfied when these potentials and the period width are the same.

[0104]

As described above, the two-terminal type active matrix liquid crystal display device of the present invention and its driving method are
By using a scanning signal having a selection period, a reset period preceding the selection period, and a current application period preceding the reset period as the scanning signal, it is possible to reduce image sticking by a simple method without side effects such as crosstalk. Is.

[Brief description of drawings]

FIG. 1 is a waveform diagram showing a scanning signal and a data signal in an example of the present invention.

FIG. 2 is a waveform diagram showing a voltage waveform applied to a liquid crystal pixel and a switching element according to a scanning signal and a data signal in the embodiment of the present invention.

FIG. 3 is a block diagram showing an active matrix liquid crystal display device using a two-terminal type switching element.

FIG. 4 is a scanning signal waveform and a data signal waveform in a driving method of a two-terminal type active matrix liquid crystal display device such as a diode or MIM of a conventional example.

FIG. 5 is a diagram illustrating a printing problem of a conventional example.

FIG. 6 is a drive waveform in a conventional method for driving a two-terminal active matrix liquid crystal display device.

[Explanation of symbols]

φ (n) nth scanning signal φ (n + 1) n + 1th scanning signal D (m) Data signal when pixel is on D ′ (m) Data signal when pixel is halftone D ″ (m) pixel Data signal T1 (n) is the first scanning period of the nth scanning signal T2 (n) is the second scanning period of the nth scanning signal T1 (n + 1) is the first scanning signal of the n + 1th scanning signal Scanning period T2 (n + 1) Second scanning period of n + 1th scanning signal Ts1 (n) First selection period Ts2 (n) Second selection period Tr1 (n) First reset period Tr2 (n) Second Reset period Ti1 (n) first current application period Ti2 (n) second current application period Vs1 first selection potential Vs2 second selection potential Vr1 first reset potential Vr2 second reset potential Vi1 first Current applied potential of Second current supply potential Vh1 first holding potential Vh2 second holding potential Vd1 first data potential Vd2 second data potential

Claims (18)

[Claims] 1. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Is a liquid crystal display device having a selection period, a reset period prior to the selection period, and a current application period prior to the reset period. 2. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period, and the scanning signal has a polarity opposite to that of the selection period and a current preceding the reset period. A liquid crystal display device, wherein the polarity of the application period is the same as that of the selection period. 3. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period preceding the selection period, and a current application period preceding the reset period, and the scanning signal has a positive selection period and a negative selection period alternately. apparatus. 4. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a positive polarity selection period and a negative polarity selection period alternately, and has a negative polarity reset period prior to the positive polarity selection period and a positive polarity current application period prior to the negative polarity reset period, A liquid crystal display device comprising a positive polarity reset period prior to a negative polarity selection period and a negative polarity current application period prior to the positive polarity reset period. 5. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a positive polarity selection period and a negative polarity selection period alternately, and has a negative polarity reset period prior to the positive polarity selection period and a positive polarity current application period prior to the negative polarity reset period, It has a positive polarity reset period prior to the negative polarity selection period, and a negative polarity current application period prior to the positive polarity reset period, and has a negative polarity negative polarity reset period prior to the scan signal positive polarity selection period. Is the same potential as the selection potential of the negative polarity selection period, and the positive polarity reset potential of the positive polarity reset period preceding the negative polarity selection period is the same potential as the selection potential of the positive polarity selection period. Is A liquid crystal display device comprising and. 6. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period, and the time width of the reset period is shorter than the time width of the selection period. . 7. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period, and the selection potential of the selection period and the current application potential of the current application period are the same potential. Display device. 8. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period prior to the selection period, and a current application period prior to the reset period, and the time width of the selection period and the time width of the current application period are equal to each other. 9. A plurality of data lines, a plurality of scanning lines, and liquid crystal pixels provided corresponding to the intersections of the data lines and the scanning lines,
A scanning signal in a liquid crystal display device having a two-terminal switching element provided corresponding to a liquid crystal pixel and driving the liquid crystal pixel according to a scanning signal applied to a scanning line and a data signal applied to a data line. Has a selection period, a reset period preceding the selection period, and a current application period preceding the reset period, and the average value of the data potential of the data signal over both the scanning signal selection period and the current application period is approximately A liquid crystal display device having a constant value. 10. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to the above, a scanning signal having a selection period, a reset period preceding the selection period, and a current application period preceding the reset period is applied to each scanning line. And a method for driving a liquid crystal display device. 11. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
The polarity of the reset period preceding the selection period is opposite to the polarity of the selection period, and the polarity of the current application period preceding the reset period is the same as that of the selection period, and a scan signal is applied to each scanning line. Driving method for liquid crystal display device. 12. A plurality of data lines and a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
A method for driving a liquid crystal display device, comprising applying a scanning signal that alternately outputs a selection period of positive polarity and negative polarity to each scanning line. 13. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels in accordance with the above, a negative polarity reset period prior to the positive polarity selection period and a negative polarity reset period that have positive polarity and negative polarity selection periods alternately. To the respective scanning lines, a scanning signal having a positive polarity current application period prior to the negative polarity selection period, a positive polarity reset period preceding the negative polarity selection period, and a negative polarity current application period preceding the positive polarity reset period. A method for driving a liquid crystal display device, which comprises applying a voltage. 14. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels in accordance with the above, a negative polarity reset period prior to the positive polarity selection period and a negative polarity reset period that have positive polarity and negative polarity selection periods alternately. The positive polarity current application period prior to the negative polarity selection period, the positive polarity reset period prior to the negative polarity selection period, and the negative polarity current application period prior to the positive polarity reset period. The negative polarity reset potential in the preceding negative polarity reset period and the selection potential in the negative polarity selection period are the same potential, and the positive polarity reset potential and the positive polarity reset potential in the positive polarity reset period preceding the negative polarity selection period are the same. Selection of selection period The driving method of a liquid crystal display device and applying a scan signal is a potential which is at the same potential to each of the scan lines. 15. A plurality of data lines and a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
A method of driving a liquid crystal display device, wherein a scan signal having a time width shorter than that of the selection period is applied to each scan line. 16. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
A driving method of a liquid crystal display device, wherein a scanning signal having the same potential as the selection potential in the selection period and the current application potential in the current application period is applied to each scanning line. 17. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
A driving method of a liquid crystal display device, wherein a scanning signal having a time width of a selection period and a time width of a current application period are applied to each scanning line. 18. A plurality of data lines, a plurality of scanning lines,
A liquid crystal pixel provided corresponding to the intersection of the data line and the scanning line, and a two-terminal switching element provided corresponding to the liquid crystal pixel, and a scanning signal applied to the scanning line and a data signal applied to the data line. In a liquid crystal display device that drives liquid crystal pixels according to, a selection period, a reset period prior to the selection period, and a current application period prior to the reset period,
A method for driving a liquid crystal display device, comprising applying a data signal to each data line in which an average value of the data potential of the data signal is substantially constant over both the selection period and the current application period.