JPH1090646A - Driving method for liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform a normal display after a device is changed over from a memory display state to a driving state by controlling voltages of pixel electrodes by a voltage control means at the time of changing over the device from a non-driving state (memory display state) in which a display is performed by a second driving method to the driving state. SOLUTION: In order to perform a bright display in the non-driving state, power source is turned off in a state in which a liquid crystal layer 14 is set to be in a planar phase by making the voltage of a pixel electrode 2 zero while impressing the voltage of a level lower than the threshold value voltage of a TFT 3 on the gate electrode 6 of the TFT 3 via an address line at the time of the driving state. Since the planar phase is a stabilized state, even when the power source is turned off, the phase state of the liquid crystal layer 14 is kept in the planar state as it is. Thus, the bright display is obtained in the non-driving state. A desired picture is displayed by controlling brightnesses and darknesses of respective pixel electrodes 2 in such a driving method.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for driving a liquid crystal display device.

[0002]

2. Description of the Related Art In recent years, liquid crystal display devices have been widely used as display devices for various devices. This is a liquid crystal display (L
CD) has advantages such as low power consumption, light weight, and low voltage driving.

As an LCD, for example, a TF using a thin film transistor (TFT) as a switching element capable of obtaining high display quality by active matrix driving is used.
DST by T-LCD and simple matrix drive
There are N-LCDs and the like, and these LCDs have become widespread mainly as personal computers and the like as thin and lightweight display devices. This type of LCD is generally a transmissive LCD that illuminates with a backlight provided on the back side thereof.

[0004] On the other hand, in recent years, with the spread of information networks, the market for portable information-driven devices, such as portable information devices, has been expanding. Here, in the transmissive LCD described above, the backlight occupies about 70% of the power consumption, so that the power consumption of the backlight needs to be reduced in order to use the battery for a long time with the battery. . However, because of its limitations,
As a display device of a portable information device or the like, a reflective LCD that does not require a backlight is more suitable.

[0005] However, the liquid crystal display mode usually used in the reflection type LCD is a TN or STN mode requiring the same polarizing plate as the transmission type LCD, so that the display screen is dark and satisfactory display quality has been obtained. Absent. For this reason,
In a reflection type LCD, a liquid crystal display mode capable of realizing a bright screen which does not require a polarizing plate is strongly demanded.

As such a liquid crystal display mode, a display method utilizing selective reflection of cholesteric liquid crystal is considered to be promising. FIG. 9 shows the voltage / reflectance characteristics of the cholesteric liquid crystal. Cholesteric liquid crystals have a property of reflecting one component of circularly polarized light in a specific wavelength region in a planar phase in a state where no voltage is applied, due to the conditions of the helical pitch and the refractive index. Thus, by optimizing the above conditions, for example, it is possible to set the reflection color to green having the highest luminosity.

When the effective voltage of the cholesteric liquid crystal is set to a predetermined level V ₂ or more when the phase state is a planar phase when no voltage is applied, the cholesteric liquid crystal has a weakly scattered focal conic phase exhibiting a translucent state. Through,
Phase transition to a transparent homeotropic phase in which the helical structure disappears. Further, when the phase state is homeotropic phase, when the cholesteric liquid crystal voltage rapidly below a predetermined level V _1, and the cholesteric liquid crystal phase transition to a planar texture, slowly to a predetermined level V ₁ or less, the focal conic texture Phase transition.

Therefore, a black layer that absorbs light is provided below the cholesteric liquid crystal layer of the reflection type LCD, and the voltage of the cholesteric liquid crystal layer at a portion corresponding to each pixel is controlled, so that the planar phase or the By selecting the homeotropic phase (or focal conic phase), it is possible to display light and dark.

Further, since the focal conic phase is in a metastable state, it is possible to maintain the focal conic phase even when no voltage is applied by optimizing the voltage control. That is, in the state where no voltage is applied (non-drive state), two stable phases of the planar phase and the focal conic phase exist.

No voltage is applied by utilizing the two stable phases (bistability) of the planar phase and the focal conic phase, that is, by utilizing the focal conic phase for black display and the planar phase for bright display. The display (memory display) is possible even in the state (non-drive state), whereby the power consumption can be further reduced.

Here, in the case of a cholesteric liquid crystal having a positive dielectric anisotropy, a difference Δε _HF between a dielectric constant in a homeotropic phase and a dielectric constant in a focal conic phase is expressed by:
Comparing the difference Δε _HP between the dielectric constant in the homeotropic phase and the dielectric constant in the planar phase, Δε _HF is smaller than Δε _HP .

Therefore, the speed (response speed) of the phase transition between the homeotropic phase and the focal conic phase is lower than that between the planar phase and the focal conic phase. Furthermore, in general, the retention in the focal conic phase is lower than that of the other phases. As a result of the cholesteric liquid crystal having such a response speed and a holding ratio, a TFT-LCD using a liquid crystal exhibiting a cholesteric liquid crystal phase as a liquid crystal layer has the following problems.

This problem will be described with reference to FIG. Here, a case where switching from a non-drive state (memory display state) in which memory display is performed to a drive state is considered. In the memory display state, the phase state of the cholesteric liquid crystal layer in the portion corresponding to the pixel performing the bright display is the planar phase. Here, when switching from the memory display state to the driving state, the TFT corresponding to the pixel performing the bright display is turned on by applying a gate voltage, and this TFT is turned on.
The effective voltage applied to the pixel electrode connected to consider the case of setting the V ₂ or more.

In this case, the response speed between the planar phase and the homeotropic phase is high, the retention rate of the planar phase is sufficient, and the leak current of the pixel electrode is small. Therefore, as shown in FIG. T following the effective voltage applied
FT is the effective voltage of the cholesteric liquid crystal layer after the OFF state becomes V ₂ or more. As a result, the portion of the cholesteric liquid crystal layer corresponding to the pixel undergoes a phase transition from the planar phase to the homeotropic phase, and the pixel performs dark display.

[0015] Here, a and again turned off TFT, when below promptly V ₁ the effective voltage of the pixel electrode, and a phase transition to a planar phase from homeotropic texture, the pixel becomes bright display again. Once in this state, the voltage control (electrical control) enables the phase transition from the planar phase to the homeotropic phase and the phase transition from the homeotropic phase to the planar phase, so that normal light and dark display is possible.

In the memory display state, the phase state of the cholesteric liquid crystal layer at the portion corresponding to the pixel performing dark display is the focal conic phase. Here, when switching from the memory display mode to the driving state, when in the ON state the corresponding TFT of the pixel that was subjected to dark display, sets the effective voltage of a pixel electrode connected to the TFT to V ₂ or more think of.

In this case, the response speed between the focal conic phase and the homeotropic phase is low, and the retention rate of the focal conic phase is low, so that the leak current of the pixel electrode increases. As shown in FIG. There is also the effective voltage applied to the pixel electrode during the on-state as V ₂ or more, the voltage of the cholesteric liquid crystal layer to be finally reached V
Less than ₂ .

As a result, the cholesteric liquid crystal layer in the portion corresponding to the above-mentioned pixel cannot undergo a phase transition from the focal conic phase to the homeotropic phase, and remains in the focal conic phase.

In this state, the phase transition to the homeotropic phase required for the phase transition to the planar phase cannot be realized by the voltage control (electrical control). Therefore, there is a problem that normal light and dark display cannot be performed after switching from the memory display state to the drive state.

[0020]

As described above, in a conventional reflection type LCD using a cholesteric liquid crystal layer, a phase transition from a focal conic phase to a homeotropic phase can be made when switching from a memory display state to a drive state. Therefore, there is a problem that normal light and dark display cannot be performed after switching from the memory display state to the drive state.

The present invention has been made in consideration of the above circumstances, and has as its object to switch from a memory display state to a driving state even when a liquid crystal having three phases such as a cholesteric liquid crystal is used. It is an object of the present invention to provide a driving method of a liquid crystal display device which can perform normal display later.

[0022]

[Means for Solving the Problems]

[Summary] In order to achieve the above object, a method for driving a liquid crystal display device according to the present invention (Claim 1) comprises a first phase having circularly polarized light selective reflection, and a second phase having no circularly polarized light selective reflection. And a liquid crystal display unit that does not have a circularly polarized light selective reflection property and controls a phase state of a liquid crystal that can take a third phase having light transmittance by an electric field to perform display. In the driving state, the liquid crystal phase state is set to the first phase by an electric field in order to display a first color, and the liquid crystal phase state is set to the third phase by an electric field in order to display a second color. And a first driving method for setting the liquid crystal display unit to the first phase in a non-driving state of the liquid crystal display unit. In order to display a first color, the liquid crystal phase state is changed to the first phase by an electric field in the driving state. In the set state, the state is switched to the non-driving state, and the driving state is switched to display the second color. A second driving method in which the liquid crystal phase state is set to the second phase or the third phase by an electric field during non-driving, and a non-driving state in which display is performed by the second driving method. And a third driving method of setting the liquid crystal to the third phase by an electric field in order to switch the liquid crystal to the driving state.

Here, in the present invention, the driving state is
A state in which an electric field is externally applied to the liquid crystal layer during at least part of a period and one period. The non-driving state indicates a state in which an electric field is not externally applied to the liquid crystal layer over the entire period.

In order to achieve the above object, another driving method of a liquid crystal display device according to the present invention (claim 2) is a method of controlling a voltage of a pixel electrode arranged in a matrix and a desired pixel electrode. A first substrate including a means and a liquid crystal layer comprising a liquid crystal exhibiting a cholesteric liquid crystal phase, wherein a liquid crystal layer having a black layer provided on a surface opposite to a surface on which light is incident is sandwiched together with the first substrate. A liquid crystal display unit comprising a liquid crystal display unit, and in the driving state of the liquid crystal display unit, in order to display a first color on a liquid crystal layer in a portion corresponding to a desired pixel electrode, the pixel electrode is controlled by the voltage control means. The voltage of the pixel electrode is controlled by the voltage control means in order to set the phase state of the liquid crystal layer in a portion corresponding to the pixel electrode to the planar phase by controlling the voltage of the pixel electrode to display a second color. By doing A first driving method of setting a phase state of a liquid crystal layer in a portion corresponding to the pixel electrode to a homeotropic phase, and a non-driving state of the liquid crystal display unit in which a liquid crystal layer in a portion corresponding to a desired pixel electrode is not driven. A state in which a phase state of a liquid crystal layer in a portion corresponding to the pixel electrode is set to a planar phase by controlling a voltage of the pixel electrode by the voltage control means in a driving state to display a first color. Controlling the voltage of the pixel electrode by the voltage control means to change the phase state of the liquid crystal layer in a portion corresponding to the pixel electrode during the driving state in order to switch to the non-drive state and display the second color. A second driving method for switching to a non-driving state in a state of being set to a focal conic phase or a homeotropic phase, and driving from a non-driving state in which display is performed by the second driving method. A third driving method for controlling the voltage of the pixel electrode by the voltage control means to set the phase state of the liquid crystal layer corresponding to the pixel electrode to the homeotropic phase in order to switch to the state. Features.

According to another aspect of the present invention, there is provided a method of driving a liquid crystal display device according to the present invention, wherein the signal voltage applying means is arranged such that A thin film transistor in which a signal voltage is applied to one source / drain, the pixel electrode is connected to the other source / drain, and an ON signal is applied to a gate. The period in which the display is switched from the non-driving state to the driving state by the second driving method is one or more frames.

Here, it is desirable that the period be an even-numbered frame of two or more frames. In order to achieve the above object, another driving method of the liquid crystal display device according to the present invention (claim 4) is the same as the driving method of the liquid crystal display device (claim 2), wherein the signal voltage applying means is one of: A signal voltage is applied to the source / drain, the pixel electrode is connected to the other source / drain, and a thin-film transistor is applied to the gate to apply an ON signal. The period in which the thin film transistor is turned on to apply the signal voltage to the pixel electrode during the period in which the display is switched from the non-drive state to the drive state in which the display is performed by the first driving method is performed by the first driving method. The phase state of the liquid crystal layer in a portion corresponding to the pixel electrode is set to a homeotropic phase by making the liquid crystal layer longer than that in the driving state being performed. Characterized in that the at it.

In order to achieve the above object, another driving method of a liquid crystal display device according to the present invention (claim 5) is the same as the driving method of the liquid crystal display device (claim 2), wherein the signal voltage applying means is A signal voltage is applied to one source / drain, the pixel electrode is connected to the other source / drain, and an ON signal is applied to a gate. The number of ON signals applied to the gate of the thin film transistor per frame period during a period of switching from the non-driving state in which display is performed by the second driving method to the driving state is set to be smaller than that in the first driving method. By increasing the number, the phase state of the liquid crystal layer in a portion corresponding to the pixel electrode is set to a homeotropic phase.

In order to achieve the above object, another method of driving a liquid crystal display device according to the present invention (Claim 6) is a method of driving a liquid crystal display device according to the present invention (Claim 2). A signal voltage is applied to one source / drain, the pixel electrode is connected to the other source / drain, and an ON signal is applied to a gate. By making the frame frequency during the period of switching from the non-drive state in which display is performed by the second drive method to the drive state higher than that in the drive state in which display is performed by the first drive method, The phase state of the liquid crystal layer corresponding to the pixel electrode is set to a homeotropic phase.

As another third driving method, in the above-mentioned liquid crystal display driving method (Claim 2), a signal voltage is applied to one source / drain while the other is applied as the signal voltage applying means. A period in which the pixel electrode is connected to the source / drain and a thin film transistor whose gate is supplied with an ON signal is used to switch from a non-driving state in which display is performed by the second driving method to a driving state; In which the level of the signal voltage applied to the source / drain of the thin film transistor is higher than that in the first driving method,
In some cases, the phase state of the liquid crystal layer corresponding to the pixel electrode is set to a homeotropic phase.

As still another third driving method, in the above-mentioned liquid crystal display device driving method (Claim 2), a signal voltage is applied to one source / drain as the signal voltage applying means, and the other is applied to the other. The pixel electrode is connected to the source / drain of the device, and a thin-film transistor having a gate to which an ON signal is applied is used to switch from the non-driving state in which display is performed by the second driving method to the driving state. In the period, the level of the ON signal applied to the gate of the thin film transistor is set higher than that in the first driving method,
In some cases, the phase state of the liquid crystal layer corresponding to the pixel electrode is set to a homeotropic phase.

[Operation] In the present invention, when switching from the non-drive state (memory display state) in which display is performed by the second drive method to the drive state, the voltage of the pixel electrode is controlled by the voltage control means. Then, the phase state of the liquid crystal layer corresponding to the pixel electrode is set to the homeotropic phase.

The phase transition from the homeotropic phase to the planar phase, and conversely, the phase transition from the planar phase to the homeotropic phase, is controlled electrically, that is, by controlling the voltage of the pixel electrode to adjust the voltage of the liquid crystal layer. You can do that. Therefore, according to the present invention, normal display can be performed after switching from the memory display state to the drive state.

[0033]

Embodiments of the present invention (hereinafter, referred to as embodiments) will be described below with reference to the drawings. (First Embodiment) FIG. 1 is a sectional view showing a liquid crystal display section of a reflective TFT-LCD according to a first embodiment of the present invention.

In FIG. 1, reference numeral 1 denotes a glass substrate (first substrate), on which pixel electrodes 2 made of ITO are arranged in a matrix. Each pixel electrode 2 has an inverted stagger type TFT as a switching element
3 are provided.

One source / drain electrode 4 of the TFT 3
Is connected to the pixel electrode 2, the other source / drain electrode 5 is connected to a signal line (not shown), and the gate electrode 6 is connected to an address line (not shown).

The structure of the TFT 3 is as follows. That is, the TFT 3 is provided on a gate electrode 6 formed on the glass substrate 1, an active layer 8 provided on the gate electrode 6 via a gate insulating film 7, and provided on a side portion of the active layer 8. And a protective insulating film 9 provided on the active layer 8.

In the figure, reference numeral 10 denotes an insulating film.
The connection between the pixel electrode 2 and the source / drain electrode 5 and the connection between the pixel electrode 2 and the source / drain electrode 4 of the adjacent TFT 3 are prevented. Further, a black layer (not shown) is provided on the pixel electrode 2 on the side in contact with the insulating film 10.

Such a pixel electrode 2, a TFT 3 and the like are integrally formed on a glass substrate 1 to constitute a TFT array substrate. In the figure, reference numeral 11 denotes another glass substrate (second substrate), and the TFT of the glass substrate 11
A counter electrode 12 to which a constant voltage is applied over the entire driving period is provided on the surface on the array substrate side.

A black matrix 13 is provided on the counter electrode 12. The black matrix 13
It is located on a region between two adjacent TFTs 2.
Such a black matrix 13 is integrally formed on the counter electrode 12 on the glass substrate 11 to form a counter substrate.

A liquid crystal layer 1 made of cholesteric liquid crystal is provided between the counter substrate and the TFT array substrate.
4 is pinched. Next, a driving method of the liquid crystal display device having the liquid crystal display unit configured as described above will be described.

First, in order to perform bright display in the normal driving state, a voltage lower than the threshold voltage of the TFT 3 is applied to the gate electrode 6 of the TFT 3 via the address line to turn off the TFT. I do.

As a result, no signal line voltage (signal voltage) is applied to the source / drain electrodes 5 of the TFT 3,
The voltage of the pixel electrode 2 becomes zero. Therefore, the liquid crystal layer 1
4 of the effective voltage becomes V ₁ or less, the liquid crystal layer 14 is set to the planar phase (first phase having a circularly polarized light selective reflective),
The reflectance of the liquid crystal layer 14 increases. Thereby, the liquid crystal layer 14
Is reflected by the liquid crystal layer 14, and a bright display (first color) is obtained.

To perform dark display in the normal driving state, a voltage higher than the threshold voltage of the TFT 3 is applied to the gate electrode 6 of the TFT 3 via the address line to turn on the TFT. I do.

As a result, a signal voltage is applied to the source / drain electrodes 5 of the TFT 3, and the voltage of the pixel electrode 2 becomes sufficiently high. Therefore, the effective voltage of the liquid crystal layer 14 is V ₂
As described above, the liquid crystal layer 14 is set to a homeotropic phase (a third phase having light transmissivity without circularly polarized light selective reflection property), and the reflectance of the liquid crystal layer 14 is reduced. Has a higher transmittance. Thereby, the light incident on the liquid crystal layer 14 passes through the liquid crystal layer 14 and is absorbed by the black layer, so that a dark display (second color) is obtained.

On the other hand, in order to perform a bright display in the non-drive state, a voltage lower than the threshold voltage of the TFT 3 is applied to the gate electrode 6 of the TFT 3 through the address line in the drive state in the pixel state. The power is turned off with the voltage of the electrode 2 set to zero to set the liquid crystal layer 14 to the planar phase. Since the planar phase is in a stable state, even if the power is turned off, the phase state of the liquid crystal layer 14 remains the planar phase. Therefore, a bright display is obtained in the non-drive state.

To perform dark display in the non-driving state, a voltage higher than the threshold voltage of the TFT 3 is applied to the gate electrode 6 of the TFT 3 via the address line in the driving state in order to perform dark display. The power is turned off while the liquid crystal layer 14 is set to a focal conic phase (a second phase having no circularly polarized light selective reflection) or a homeotropic phase by setting the voltage of the electrode 2 to a voltage equal to or higher than V _1. .
Since the voltage applied to the liquid crystal layer 14 gradually decreases due to the off-state TFT and the leak current of the liquid crystal layer itself, the phase state of the liquid crystal layer 14 becomes a focal conic phase. Therefore, a dark display is obtained in the non-drive state.

By controlling the brightness of each pixel electrode 2 by such a driving method, a desired image can be displayed. This is a signal line like a normal LCD,
It can be performed by controlling the ON / OFF of each TFT 3 by the address line.

Here, in the non-drive state (memory display state) in which the memory display is being performed, the state power supply is off, so that the voltage of the pixel electrode cannot be changed. Therefore, in the memory display state, the image is a still image. That is, the image immediately before the power is turned off is displayed.

Up to this point, the operation is the same as that of the conventional LCD.
Next, a driving method for switching from a memory display state to a normal driving state (normal driving state), which is a feature of the present embodiment, will be described. FIG. 2 shows a timing chart of this driving method.

In the figure, V _g is the gate voltage (ON signal), V
_sig is the signal voltage, V _com is the signal voltage of the common electrode, V
_sig.c indicates the center of the signal voltage V _sig . The effective voltage is that of the liquid crystal layer 14.

It should be noted that in the figure, for simplicity of explanation,
A method of darkly displaying the entire screen over several frames during a normal driving period is shown. The same applies to the drawings of other embodiments.

In this embodiment, when the power is turned on to switch from the memory display state to the normal driving state (normal driving state) (driving start period), the dark display is performed during the normal driving state period (normal driving period). Is applied to the source / drain electrode 5 with a signal voltage having a larger amplitude than the signal voltage applied to the source / drain electrode 5.

As a result, during the driving start period, the source
The voltage of the drain electrode 5 is higher than the voltage of the source / drain electrode 5 during the normal driving period. Therefore,
The effective voltage V _A of the liquid crystal layer 14 during the driving start period is higher than the effective voltage V _B of the liquid crystal layer 14 during the normal driving period. Thereby, the liquid crystal layer 14 in the dark display state of the focal conic phase can be changed in phase to the dark display state of the homeotropic phase.

In other words, a signal voltage having a high amplitude enough to compensate for the slowness of the phase transition between the focal conic phase and the homeotropic phase (response speed) and the low retention rate of the focal conic phase is applied to the pixel electrode. This ensures that the phase transition from the focal conic phase to the homeotropic phase occurs.

As described above, according to the present embodiment, in the memory display state, the liquid crystal layer 14 in the dark display state of the focal conic phase can be changed to the homeotropic phase dark display state. Can display light and dark by a normal driving method.

When the effective voltage of the liquid crystal layer 14 is V _A (> V
_{Since B} ) occurs only during the driving start period, there is almost no increase in power consumption, and the power consumption is almost the same as that of the related art. Therefore, the LCD of the present embodiment is effective as a display device of a portable information device similarly to the conventional LCD.

In the present embodiment, the driving start period is set to two frames, but may be one frame or three or more frames. However, it is desirable that the frames are even-numbered so that the applied signals have the same positive and negative polarities.

Also, in the case of so-called common inversion driving in which the common electrode on the opposite electrode side is inverted and driven,
As shown in FIG. 3, a similar effect can be obtained by making the amplitude of the signal V ′ _com applied to the common electrode in the drive start period larger than that of the signal amplitude V _com in the normal drive period.

FIG. 3 shows an example of frame common inversion drive in which the polarity is inverted for each frame.
The same effect can be obtained in the H common inversion drive in which the polarity is inverted during the horizontal period. (Second Embodiment) FIG. 4 is a timing chart showing a driving method for switching from a memory display state to a normal driving state according to a second embodiment of the present invention. In the following embodiments, the structure of the LCD and the method of light / dark display in the driving display and the non-driving display are the same as those in the first embodiment, and thus the description thereof will be omitted.

In this embodiment, during the driving start period, T
The amplitude V _g H ′ of the gate voltage (on-voltage) applied to the gate electrode 6 of the FT 3 is changed during the normal driving period.
Is higher than the amplitude V _g H of the gate voltage (ON voltage) applied to the gate electrode 6.

When the amplitude of the gate voltage during the driving start period increases, the current I _DS flowing between the source and the drain of the TFT 3 is increased.
Since the current value of the
The amount of charge stored in the liquid crystal layer 14 via the drain electrode 5 becomes larger than that in the normal driving period.

Therefore, similarly to the first embodiment, the liquid crystal layer 14 in the dark display state of the focal conic phase in the memory display state can be changed to the homeotropic phase dark display state. Thereafter, light and dark display can be performed by a normal driving method.

When the amplitude of the gate voltage is V _g H '(> V
_g H) is only during the driving start period, and therefore, there is almost no increase in power consumption, and the power consumption is almost equal to that of the related art. Therefore, the LCD of the present embodiment is effective as a display device of a portable information device similarly to the conventional LCD.

When the amplitude of the gate voltage is V _g H '(> V
_g H) only during the drive start period, so TF
TFT characteristics hardly deteriorate with time due to application of a high-level gate voltage to the gate electrode 6 of T3. (Third Embodiment) FIG. 5 is a timing chart showing a driving method for switching from a memory display state to a normal driving state according to a third embodiment of the present invention.

In the present embodiment, during the driving start period, T
The period during which a gate voltage (ON signal) having a level equal to or higher than the threshold voltage of the TFT 3 is applied to the gate electrode 6 of the FT 3 is longer than the period during which the ON signal is applied to the gate electrode 6 of the TFT 3 in the normal driving period. . The figure shows a case where the application time of the ON signal in the driving start period of all the TFTs 3 is increased by selecting all the address lines.

When the application time of the ON voltage becomes longer, the amount of electric charge stored in the liquid crystal layer 14 becomes larger than that in the normal driving period, and the voltage applied to the liquid crystal by the leak current of the TFT 3 and the liquid crystal layer 14 decreases. The holding period to be performed is short.

Accordingly, similarly to the first embodiment, the liquid crystal layer 14 in the dark display state of the focal conic phase in the memory display state can be changed to the homeotropic phase dark display state. Thereafter, light and dark display can be performed by a normal driving method. In this embodiment, since all the address lines are selected, the entire screen is temporarily darkened and refreshed.
Thereafter, light and dark display is performed by a normal driving method.

According to the present embodiment, unlike the first and second embodiments, a new level is set in the signal line driver to increase the voltage of the signal line, Since it is not necessary to set a new level in the address line driver to increase the voltage, a simpler circuit configuration than in the first and second embodiments can be used. (Fourth Embodiment) FIG. 6 is a timing chart showing a driving method for switching from a memory display state to a normal driving state according to a fourth embodiment of the present invention.

In this embodiment, 1 is used in the driving start period.
The number of ON signals per frame period applied to the gate electrode 6 in units of one or more TFTs 3 is set to be larger than that in the normal driving period.

In this case as well, during the driving start period, the TFT
Since the period during which the ON signal is applied to the third gate electrode 6 is extended, the same effect as in the third embodiment can be obtained. (Fifth Embodiment) FIG. 7 is a timing chart showing a driving method for switching from a memory display state to a normal driving state according to a fifth embodiment of the present invention.

In this embodiment, 1 is used in the driving start period.
The period during which an ON signal is applied to the gate electrode 6 for each TFT or a plurality of TFTs 3 is set longer than that in the normal driving period.

Also in this case, in the driving start period, the TFT
Since the period during which the ON signal is applied to the third gate electrode 6 is extended, the same effect as in the third embodiment can be obtained. (Sixth Embodiment) FIG. 8 is a timing chart showing a driving method for switching from a memory display state to a normal driving state according to a sixth embodiment of the present invention.

In the present embodiment, the frame frequency during the drive start period is higher than that during the normal drive period. When the frame frequency increases, the number of ON signals per unit time increases, and the holding period of the liquid crystal layer 14 can be short. Therefore, the liquid crystal layer 14 in the dark display state of the focal conic phase in the memory display state can be used. As a result, the phase transition can be made to a dark state of the homeotropic phase. Therefore, after that, the light and dark display can be performed by the normal driving method.

Since the frame frequency is increased only during the driving start period, the power consumption hardly increases.
The power consumption is almost equal to the conventional one. Therefore, the LCD of the present embodiment is effective as a display device of a portable information device similarly to the conventional LCD.

The present invention is not limited to the embodiment described above. For example, in the above embodiment, a TFT is used as a switching element, but another element may be used.

Further, the above embodiments may be variously combined. For example, both the amplitude of the ON signal and the application time of the ON signal during the drive start period may be made longer than those during the normal drive period.

In the above embodiment, the case of the reflection type LCD which does not require a backlight has been described. However, the present invention can be applied to a transmission type LCD using a backlight.
In addition, various modifications can be made without departing from the scope of the present invention.

[0078]

As described above in detail, according to the present invention, when switching from the non-driving state (memory display state) to the driving state in which the second driving method is performed, the voltage control means controls the pixel electrodes. By controlling the voltage, the phase state of the liquid crystal layer in the portion corresponding to the pixel electrode is set to the homeotropic phase, so that normal display can be performed after switching from the memory display state to the drive state.

[Brief description of the drawings]

FIG. 1 shows a reflective TFT according to a first embodiment of the present invention.
Sectional view showing a liquid crystal display section of an LCD

FIG. 2 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to the first embodiment of the present invention;

FIG. 3 is a diagram showing a modification of the first embodiment;

FIG. 4 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to a second embodiment of the present invention.

FIG. 5 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to a third embodiment of the present invention.

FIG. 6 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to a fourth embodiment of the present invention.

FIG. 7 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to a fifth embodiment of the present invention.

FIG. 8 is a diagram showing a driving method for switching from a memory display state to a normal driving state according to a sixth embodiment of the present invention.

FIG. 9 is a diagram showing a voltage / reflectance characteristic of a cholesteric liquid crystal;

FIG. 10 is a view for explaining a problem of a conventional reflection type LCD using a cholesteric liquid crystal layer.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Glass substrate (1st substrate) 2 ... Pixel electrode 3 ... TFT 4 ... Source / drain electrode 5 ... Source / drain electrode 6 ... Gate electrode 7 ... Gate insulating film 8 ... Active layer 9 ... Protective insulating film 10 ... Insulation Film 11: glass substrate (second substrate) 12: counter electrode 13: black matrix 14: liquid crystal layer

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor, etc.Kobayashi et al. 33, Shinisogo-cho, Isogo-ku, Yokohama-shi, Kanagawa Prefecture Inside Toshiba Production Technology Research Institute Co., Ltd. Address Co., Ltd., Toshiba Production Technology Laboratory

Claims (6)

[Claims] 1. A first phase having circularly polarized light selective reflection, a second phase having no circularly polarized light selective reflection, and a third phase having no circularly polarized light selective reflection and having light transmittance. A liquid crystal display unit that controls the liquid crystal phase state by an electric field to perform display. In the driving state of the liquid crystal display unit, a phase of the liquid crystal is displayed by the electric field to display a first color. A first driving method of setting a state of the liquid crystal to the third phase by an electric field to set a state to the first phase and display a second color; In the driving state, in order to display the first color, in the driving state, the liquid crystal is switched to the non-driving state with the phase state of the liquid crystal set to the first phase by an electric field, and the second color is displayed. Therefore, in the driving state, the phase state of the liquid crystal is changed to the second phase by an electric field. A second driving method for switching during non-driving in the state set to the second phase; and for switching from the non-driving state in which display is performed by the second driving method to the driving state, the liquid crystal is driven by an electric field. And a third driving method for setting the phase to the third phase. A first substrate including a pixel electrode arranged in a matrix, a voltage control means for controlling a voltage of a desired pixel electrode, and a liquid crystal exhibiting a cholesteric liquid crystal phase;
A liquid crystal display comprising a liquid crystal layer having a black layer provided on a surface opposite to a surface on which light is incident and a second substrate sandwiching the liquid crystal layer together with the first substrate; In the state, the voltage of the pixel electrode is controlled by the voltage control means in order to display the first color on the liquid crystal layer of the portion corresponding to the desired pixel electrode. To set the phase state of the layer to the planar phase and display the second color,
A first driving method of setting a phase state of a liquid crystal layer in a portion corresponding to the pixel electrode to a homeotropic phase by controlling a voltage of the pixel electrode by the voltage control unit; In the state, in order to display the first color on a portion of the liquid crystal layer corresponding to a desired pixel electrode,
In the driving state, the phase state of the liquid crystal layer corresponding to the pixel electrode is switched to the non-driving state in a state where the liquid crystal layer is set to the planar phase by controlling the voltage of the pixel electrode by the voltage control means. In order to display a color, the phase state of the liquid crystal layer corresponding to the pixel electrode in the driving state is set to a focal conic phase or a homeotropic phase by controlling the voltage of the pixel electrode by the voltage control means. 2nd to switch when not driven in the state
And the voltage control means controls the voltage of the pixel electrode in order to switch from the non-driving state in which display is performed by the second driving method to the driving state, thereby controlling the voltage corresponding to the pixel electrode. And a third driving method for setting the phase state of the liquid crystal layer to a homeotropic phase. 3. The method according to claim 2, wherein the signal voltage applying means includes one source
A signal voltage is applied to the drain, the pixel electrode is connected to the other source / drain, and a thin-film transistor is applied to the gate to apply an ON signal. Display is performed by the third driving method and by the second driving method. 3. The driving method for a liquid crystal display device according to claim 2, wherein the period of switching from the non-driving state to the driving state is one or more frames. 4. The signal voltage applying means includes one source
A signal voltage is applied to a drain, the pixel electrode is connected to the other source / drain, and a thin-film transistor is applied to a gate to apply an ON signal. The third driving method is a display according to the second driving method. In the period in which the thin film transistor is turned on to apply the signal voltage to the pixel electrode during the period of switching from the non-driving state to the driving state, the driving is performed by the first driving method. The method according to claim 2, wherein the phase state of the liquid crystal layer in a portion corresponding to the pixel electrode is set to a homeotropic phase by making the liquid crystal layer longer than that in the state. 5. The apparatus according to claim 1, wherein said signal voltage applying means includes one source
A signal voltage is applied to a drain, the pixel electrode is connected to the other source / drain, and a thin-film transistor is applied to a gate to apply an ON signal. The third driving method is a display according to the second driving method. The number of ON signals applied to the gate of the thin film transistor per frame period during the period of switching from the non-driving state to the driving state during which the pixel driving is performed is made larger than that in the first driving method. 3. The method according to claim 2, wherein a phase state of the liquid crystal layer corresponding to the electrode is set to a homeotropic phase. 6. The signal voltage applying means includes one source
A signal voltage is applied to a drain, the pixel electrode is connected to the other source / drain, and a thin-film transistor is applied to a gate to apply an ON signal. The third driving method is a display according to the second driving method. The frame frequency during the period of switching from the non-driving state to the driving state is higher than that in the driving state in which display is performed by the first driving method, so that the liquid crystal in the portion corresponding to the pixel electrode is changed. 3. The method according to claim 2, wherein the phase state of the layer is set to a homeotropic phase.