JPH09304753A - Liquid crystal device driving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable stable gradation control and contrast control by applying an initialization voltage at the start of each drive period, and thereafter, applying a pixel voltage answering to the display data. SOLUTION: A drive voltage correction part 24 outputs a drive voltage Vh corrected to the voltage corresponding to temp. dependency of an applied voltage transmissivity characteristic of a high polymer distributed type display panel based on the temp. data Dt outputted from a temp. detection part 23. An initialization processing part 22 outputs the initialization data Dc at the start of each drive period T only for the period that an initialization timing signal Fc is valid. A drive signal conversion part 25 inputs the drive voltage Vh outputted from the drive voltage correction part 24 as a voltage source. Further, the part 25 inputs the initialization data Dc outputted from the initialization processing part 22, and converts them into the pixel voltage to apply it to the high polymer distributed type liquid crystal panel 26. Thus, an effect of hysteresis peculiar to the high polymer distributed type liquid crystal panel is canceled.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of driving a liquid crystal display device. More particularly, it relates to a driving method of a liquid crystal display device including a polymer dispersed liquid crystal panel.

[0002]

2. Description of the Related Art Liquid crystal display devices are widely used as display panels for devices for various purposes because they have many excellent features such as thinness and low power consumption. In recent years, as a liquid crystal display panel, a polymer-dispersed liquid crystal panel has attracted attention as a liquid crystal display panel that does not require a polarizing plate and has a very high light utilization efficiency and is capable of displaying paper white.

The polymer-dispersed liquid crystal panel has a milky white display due to the light scattering effect when no voltage is applied (OFF state), and loses the light scattering effect when the voltage is applied (ON state), resulting in a transparent display. It becomes a state. A polymer-dispersed liquid crystal panel has a polymer layer disposed between a pair of electrode substrates provided with transparent electrodes on at least one side. Is dispersed (hereinafter, referred to as a polymer-dispersed liquid crystal layer), and a polarizing plate and an alignment film are generally unnecessary.

The liquid crystal panel currently in the mainstream is ST
Such as N (super twisted nematic) panel and TN type TFT (twisted nematic type thin film transistor) panel. Since these liquid crystal panels use polarizing plates, the light utilization efficiency is theoretically 50%.
It is the following.

Since the polymer dispersion type liquid crystal panel does not need a polarizing plate, it is possible to increase the light utilization efficiency to 80% or more. Therefore, in recent years, it has begun to be used for a projection type liquid crystal display device and the like. FIG. 7 is a structural diagram of a general polymer-dispersed liquid crystal display panel. A pair of transparent substrates (for example, glass substrates) 11 and 12 provided with transparent electrodes 13 and 14 are provided with a frame-shaped sealing material 15 interposed therebetween. The structure is such that the polymer dispersed liquid crystal layer 16 is provided in the bonded cell 10.

FIG. 8 is a partially enlarged view of the polymer-dispersed liquid crystal layer 16, in which a liquid crystal (nematic liquid crystal having a positive dielectric anisotropy) 18 is contained in the polymer 17 layer in the form of small droplets or fine continuous particles. The structure is dispersed as a phase. The polymer-dispersed liquid crystal display panel shown in FIG. 7 is one in which a voltage is applied between electrodes 13 and 14 provided on a pair of substrates 11 and 12 to display a predetermined image. The molecules of the liquid crystal 18 in 16 are oriented in various directions when no voltage is applied, and in this state, the light incident on the polymer dispersed liquid crystal layer 16 is reflected at the interface between the liquid crystal 18 and the polymer 17. The light is scattered by the light scattering action, and the display becomes a cloudy state.
This state is the dark state.

On the other hand, a liquid crystal 18 is provided between the electrodes 13 and 14.
When a voltage equal to or higher than the threshold voltage is applied, the molecules of the liquid crystal 18 are aligned substantially perpendicular to the surfaces of the substrates 11 and 12. In this state, the light scattering action at the interface between the liquid crystal 18 and the polymer 17 disappears, and the incident light passes through the polymer-dispersed liquid crystal layer 16 almost as it is. Therefore, the light transmittance increases and the display becomes a bright state. Become.

That is, the polymer dispersion type liquid crystal display panel displays a desired pattern by light scattering (dark state) and transmission (bright state) without using a polarizing plate.
S that requires a deflector that is commonly used today
Compared with the TN type liquid crystal display panel and the TN type TFT liquid crystal display panel, the light utilization efficiency is very high and the display screen is bright.
It has the advantage of being able to display paper white and has a wide viewing angle.

In this polymer-dispersed liquid crystal display panel, since the light scattering degree by the liquid crystal changes according to the value of the voltage applied between the electrodes 13 and 14, the light transmittance, that is, the display brightness. Gradation display in which the height is arbitrarily selected is also possible.

[0010]

However, when the polymer dispersion type liquid crystal display panel is displayed by changing the pixel voltage applied between the electrodes 13 and 14 to various values in each driving cycle, The pixel voltage value and the light transmittance do not have a one-to-one correspondence, and the gradation control is almost impossible.

This is because the applied voltage-transmittance characteristic of the polymer dispersed display panel has hysteresis. 5 and 6 are explanatory diagrams of this hysteresis characteristic. As shown in FIG. 5, the polymer-dispersed liquid crystal panel shows a characteristic curve of applied voltage-transmittance when the absolute value of applied voltage is gradually increased, and a characteristic curve when the absolute value of applied voltage is gradually decreased. The applied voltage-transmittance characteristic curves are not the same. That is, it has a hysteresis characteristic. Therefore, the transmittance when the applied voltage is changed from V ₀ to V ₁ is T ₂ , but the transmittance when the applied voltage is changed from V ₂ to V ₁ is T ₁ . Further, as shown in FIG. 6, a number of different hysteresis curves are generated depending on the starting point and the direction in which the applied voltage changes. As described above, the polymer dispersion type display panel has a rather troublesome problem called a hysteresis phenomenon, which is a great obstacle in performing gradation display.

Next, regarding the temperature dependence of various characteristics of the polymer dispersion type liquid crystal display panel, such as applied voltage-transmittance characteristic and hysteresis characteristic, generally, a TN type liquid crystal display panel and an STN type liquid crystal display panel. It is much larger than the temperature dependence of. FIG. 9 shows the temperature dependence of the applied voltage-transmittance characteristic and the temperature dependence of the hysteresis characteristic of the polymer dispersion type liquid crystal display panel. As shown in this figure, regarding the temperature dependence of the hysteresis characteristic of the polymer-dispersed liquid crystal display panel, the curve of the hysteresis characteristic greatly differs depending on the temperature, and the hysteresis characteristic tends to increase as the temperature becomes lower.

Therefore, the temperature dependence of various characteristics (for example, applied voltage-transmittance characteristic, hysteresis characteristic, etc.) of the polymer dispersion type liquid crystal display panel is a major obstacle to realizing good gradation display and display contrast. Becomes Due to these problems, it has heretofore been very difficult to realize good gradation display and display contrast using a polymer dispersion type liquid crystal display panel.

[0014]

As described above, in the conventional liquid crystal display device, it is difficult to control the gradation in correspondence with the hysteresis characteristic peculiar to the polymer dispersion type liquid crystal panel, and good gradation expression can be achieved. There was a problem that I could not get it. Also,
It is difficult to perform contrast control and gradation control corresponding to the temperature dependence of various characteristics (for example, applied voltage-transmittance characteristic, hysteresis characteristic, etc.) of the polymer dispersed liquid crystal display panel, and it is possible to obtain a good gradation. There was a problem that expression and display contrast could not be obtained.

The liquid crystal display device of the present invention has been made in order to solve such a problem, and largely eliminates the influence of the hysteresis characteristic peculiar to the polymer dispersion type liquid crystal panel.
Stable gradation control and contrast control are possible, and drive voltage control is made to correspond to the temperature dependence of various characteristics of polymer-dispersed liquid crystal panel (for example, applied voltage-transmittance characteristic, hysteresis characteristic, etc.). It is an object of the present invention to provide a liquid crystal display device capable of realizing stable and excellent display contrast and gradation expression even when the ambient temperature fluctuates.

In order to achieve the above-mentioned object, the liquid crystal display device of the present invention has a polymer dispersion type liquid crystal panel in which the degree of light scattering is changed by applying a pixel voltage corresponding to display data. In that driving method, the initialization voltage is applied at the beginning of each driving cycle, and thereafter,
This is a driving method in which a pixel voltage corresponding to display data is applied. Further, the initialization voltage is an applied voltage at which the light transmittance of the liquid crystal display device is almost maximum. Further, the ratio of the application time of the initialization voltage and the application time of the display data for each drive cycle is a drive method in which the application time of the initialization voltage is 1 and the application time of the display data is 3 or more.

In the liquid crystal display device of the present invention, a timing generating means for controlling the timing of the application time of the initialization voltage and the application time of the display data in each drive cycle, and the input display signal. Gradation conversion means for converting into digital voltage data, initialization processing means for applying an initialization voltage at the beginning of each driving cycle, digital voltage data converted by the gradation conversion means or the initialization Drive signal conversion means for converting the initialization data output from the processing means into a pixel voltage of the liquid crystal display panel,
Temperature detection means for detecting the environmental temperature in the vicinity of the liquid crystal display panel, and a drive voltage corresponding to the temperature dependency of the applied voltage-transmittance characteristic of the liquid crystal display panel based on the temperature data output from the temperature detection means. A driving voltage correction means for correction is provided.

With the above-mentioned means, the driving method of the liquid crystal display device according to the present invention applies the applied voltage as the initialization voltage at the beginning of each driving cycle so that the light transmittance of the liquid crystal display panel is almost maximum. After that, since the pixel voltage corresponding to the display data is applied, the state of the liquid crystal immediately before the application of the pixel voltage is the same in any driving cycle. Therefore, the correspondence relationship between the value of the pixel voltage and the transmittance is It is almost always constant. Thereby, the influence of the hysteresis characteristic peculiar to the polymer dispersed liquid crystal panel can be largely eliminated.

Further, in the driving method of the liquid crystal display device of the present invention, the ratio of the application time of the initialization voltage and the application time of the display data is expressed as follows: Since the control is performed so as to be 3 or more, deterioration of the display contrast due to the application of the initialization voltage can be significantly reduced, and good display contrast quality can be obtained.

Further, since the liquid crystal display device of the present invention comprises the temperature detecting means and the driving voltage correcting means,
Since the drive voltage of the liquid crystal display device can be controlled according to the fluctuation of the ambient temperature, the contrast corresponding to the temperature dependence of various characteristics (for example, applied voltage-transmittance characteristic, hysteresis characteristic, etc.) of the polymer dispersed liquid crystal panel. Control and gradation control are possible, and stable and favorable display contrast and gradation expression can be realized.

[0021]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a main configuration of an embodiment of the present invention, and FIG. 2 shows a drive voltage waveform applied between electrodes of a polymer dispersion type liquid crystal display panel. The timing generator 20 controls the timing of the initialization period Tc and the display data application period Td in each driving cycle T, and outputs the initialization timing signal Fc and the display timing signal Fd. The initialization timing signal Fc is input to the initialization processing unit 22, and the display timing signal Fd is input to the gradation conversion unit 21. The valid period of the initialization timing signal Fc and the valid period of the display timing signal Fd are mutually exclusive.

The gradation converter 21 has a display signal input terminal Ain, and converts an analog display signal input from this terminal into digital voltage data Dk. The output timing of the digital voltage data Dk is the display timing signal F.
d is output only during a valid period, and the drive signal conversion unit 25
Is input to The digital display data (that is, the digital voltage data Dk) is not output during the period when the display timing signal Fd is not effective.

In order to largely eliminate the influence of the hysteresis peculiar to the polymer dispersed liquid crystal panel, the initialization processing section 22 sets the initialization data Dc at the beginning of each driving cycle T only during the period when the initialization timing signal Fc is effective. Output. The initialization data Dc is input to the drive signal converter 25.
Note that the initialization data Dc is not output while the initialization timing signal Fc is not valid.

Further, the temperature detector 23 detects the environmental temperature near the liquid crystal display panel 26. Drive voltage correction unit 24
The temperature data Dt output from the temperature detector 23 is input, and the drive voltage of the liquid crystal display panel 26 is corrected based on the temperature data Dt. Drive signal converter 25
Is the drive voltage V output from the drive voltage correction unit 24.
Input h as a voltage source. Further, the digital voltage data Dk output from the gradation conversion unit 21 or the initialization data Dc output from the initialization processing unit 22 is input, converted into a pixel voltage, and applied to the polymer dispersed liquid crystal panel 26. .

As a result, the influence of the hysteresis peculiar to the polymer dispersed liquid crystal panel can be largely eliminated, the gradation control and the contrast control corresponding to the digital voltage data can be performed, and at the same time, the application of the polymer dispersed liquid crystal panel can be performed. Since the drive voltage corresponding to the temperature dependency of the voltage-transmittance can also be controlled, good gradation expression and contrast can be realized even if the environmental temperature changes.

Next, a driving method of the liquid crystal display device of the present invention will be described with reference to FIGS. FIG. 2 is a waveform diagram of a drive voltage applied between electrodes of the polymer dispersed liquid crystal display panel. FIG. 3 is a diagram showing a voltage-transmittance characteristic of the polymer dispersed liquid crystal display panel when driven by the driving voltage of FIG.

The driving method of this embodiment will be described with reference to FIG.
In the drive method of this embodiment, T is a drive cycle for applying a drive voltage for one frame between the electrodes. In the drive method of the present embodiment, an initialization period for initializing the previous display state at the beginning of each drive cycle T. Tc is provided. After that, an application period Td for displaying new display data is provided. Further, the application period ratio of the initialization period Tc and the display data application period Td is controlled so that the initialization data period Tc is 1 and the display data application period Td is 3 or more.

Then, in this embodiment, at the beginning of each driving cycle T, as the initialization voltage Vc for initializing the previous display state, the display pixel voltage Vd at which the light transmittance of the liquid crystal display panel is almost maximum is obtained. (Max) is applied for the initialization period Tc, and then the pixel voltage Vd according to new display data is applied for the display application period Td. The initialization voltage Vc and the display pixel voltage Vd are set so that the voltage of the DC component is not biased to the liquid crystal of the polymer dispersed liquid crystal panel.
The waveform pulse voltage shown in FIG. 2 in which the polarity is alternately inverted every same number of times is used. It should be noted that the initialization voltage Vc depends on which drive cycle T
Also has the same value.

The display pixel voltage Vd is a pixel voltage controlled to various values according to display data. The value of the display pixel voltage Vd applied in each drive cycle T is the maximum display pixel voltage Vd (Max) and the minimum display pixel voltage Vd (M
in) corresponds to the maximum (Ymax) and the minimum (Ymin) of the light transmittance (or the minimum (Ymin) and the maximum (Ymax), respectively) in the case of the transmissive polymer dispersed liquid crystal panel.

By applying such a driving waveform,
The state of the polymer-dispersed liquid crystal just before applying the pixel voltage Vd corresponding to the display data is almost the same in any driving cycle T. If the state of the polymer dispersed liquid crystal just before applying the pixel voltage Vd corresponding to the display data is almost the same, the correspondence between the pixel voltage and the transmittance of the polymer dispersed liquid crystal panel is always constant. Since it is almost constant, the influence of the hysteresis characteristic peculiar to the polymer dispersed liquid crystal panel can be largely eliminated.

In general, the polymer-dispersed liquid crystal panel has a hysteresis characteristic as shown in FIG. 6 in applied voltage-transmittance characteristic. Therefore, there are many variations depending on the starting point and the changing direction of the pixel voltage. Draw a hysteresis curve.
In the driving method of the present embodiment, the display pixel voltage Vd (Max) that maximizes the light transmittance of the polymer dispersed liquid crystal panel is applied as the initialization voltage Vc at the beginning of each driving cycle, and then the display data is applied to the display data. Since the corresponding display pixel voltage Vd is applied, the applied voltage-transmittance characteristic of the polymer dispersed liquid crystal panel according to the driving method of the present embodiment is as shown in FIG. 3, with respect to the change of the display pixel voltage Vd. A characteristic curve L showing a specific applied voltage-transmittance is obtained. That is, the applied voltage-transmittance characteristic curve L of the polymer-dispersed liquid crystal panel according to the driving method of the present embodiment starts from the point a of the maximum transmittance (Ymax) of the applied voltage-transmittance characteristic shown in FIG. As the pixel voltage V
The curve L (solid line) shows the characteristic of applied voltage-transmittance when d is lowered.

Therefore, when the polymer dispersion type liquid crystal panel is driven by the driving method of the present invention, the phenomenon that a number of different hysteresis curves are generated due to the difference between the starting point and the changing direction of the pixel voltage, which has been a conventional problem, is solved. A specific pixel voltage-transmittance characteristic curve L starting from a point a of maximum transmittance (Ymax) corresponding to the initialization voltage Vc
Therefore, the influence of the hysteresis characteristic peculiar to the polymer dispersion type liquid crystal panel can be largely eliminated. Therefore, since the transmittance corresponding to the display data is uniquely obtained, the gradation control can be performed, and the excellent gradation display can be realized.

Next, FIG. 4 shows changes in the display contrast of the polymer dispersion type liquid crystal display panel due to the difference in the application period ratio between the initialization period Tc and the display data application period Td. The horizontal axis of FIG. 4 is the application time ratio [Tc / (Tc +
Td)], and the vertical axis is the display contrast index. still,
The display contrast index is a contrast ratio [Cr (Tc)] with the display contrast Cr (Tc) during an arbitrary initialization period Tc based on the display contrast Cr (Tc = 0) when the initialization period Tc = 0. / Cr (Tc = 0)]
It is a numerical value defined by. As is clear from FIG. 4,
The degree of deterioration of the display contrast increases in proportion to the increase of the ratio of the initialization period Tc to the driving cycle T. From these facts, the application period ratio of the initialization period Tc and the display data application period Td in which the display contrast deterioration is not a practical problem is set such that the initialization data period Tc is 1 and the display data application period Td is 3 or more. It was found to be time. Incidentally, more preferably, the initialization period Tc
Is 1 and the display data application period Td is 6 or more. In this way, by controlling the application period ratio of the initialization period Tc and the display data application period Td, it is possible to greatly reduce the deterioration of the display contrast due to the application of the initialization voltage, and to obtain a good display contrast quality. Obtainable.

Here, the driving method using a low voltage such as the minimum display pixel voltage Vd (Min) as the initialization voltage Vc is the display quality (for example, contrast or responsiveness) of the polymer dispersed liquid crystal display panel. Etc.) is not preferable as the driving method of the present invention. The reason for this is that the response speed of polymer-dispersed liquid crystal display panels is generally
The falling response speed (ON to OFF) is considerably slower than the rising response speed (OFF to ON), and the falling response speed is difficult to control the voltage as compared with the rising response speed. It has been confirmed that it is very difficult to obtain a satisfactory display quality (for example, contrast and responsiveness) with the driving method of (1).

Next, the processing of each component of FIG. 1 will be specifically described. The temperature detection unit 23 includes a liquid crystal display panel 26.
The environmental temperature in the vicinity is detected and the temperature data Dt is output.
The drive voltage correction unit 24 receives the temperature data Dt output from the temperature detection unit 23, and based on the temperature data Dt, corresponds to the temperature dependence of the applied voltage-transmittance characteristic of the polymer dispersed liquid crystal display panel. Drive voltage V
Output h. The drive voltage Vh is input to the drive signal converter 25 and serves as a voltage source for the drive signal converter 25. The timing generator 20 controls the timing of the initialization period Tc and the display data application period Td in each drive cycle T, and the initialization timing signal Fc and the display timing signal F
Output d. The initialization timing signal Fc is input to the initialization processing unit 22, and the display timing signal Fd is input to the gradation conversion unit 21. The valid period of the initialization timing signal Fc and the valid period of the display timing signal Fd are mutually exclusive.

The initialization processing section 22 sets the initialization data Dc at the beginning of each drive cycle T and a period during which the initialization timing signal Fc is effective in order to largely eliminate the influence of the hysteresis peculiar to the polymer dispersed liquid crystal panel. Output only. The initialization data Dc is input to the drive signal converter 25. The initialization data Dc is not output during the period when the initialization timing signal Fc is not valid.

The gradation conversion unit 21 having the display signal input terminal Ain converts the analog display signal input from this input terminal into digital voltage data Dk. The output timing of the digital voltage data Dk is output only during a period in which the display timing signal Fd is valid and is input to the drive signal conversion section 25. The display timing signal Fd
The digital voltage data Dk, which is digital display data, is not output during the period when is not effective.

The drive signal converter 25 receives the drive voltage Vh output from the drive voltage corrector 24 as a voltage source. Further, the digital voltage data Dk output from the gradation conversion unit 21 or the initialization data Dc output from the initialization processing unit 22 is input, converted into a pixel voltage, and applied to the polymer dispersed liquid crystal panel 26. .

As a result, the influence of the hysteresis peculiar to the polymer dispersed liquid crystal panel can be largely eliminated, and the gradation control corresponding to the digital voltage data can be performed, and at the same time,
Since the drive voltage control corresponding to the temperature dependence of the applied voltage-transmittance of the polymer-dispersed liquid crystal panel can also be performed, good gradation expression and display contrast can be realized even if the environmental temperature changes. .

[0040]

As described above, according to the liquid crystal display device of the present invention, a voltage that maximizes the light transmittance of the liquid crystal display panel is applied as an initialization voltage at the beginning of each driving cycle,
After that, the pixel voltage corresponding to the display data is applied, and the application time ratio of the application time of the initialization voltage and the application time of the display data is calculated by comparing the application time of the initialization voltage with the application time of the display data. Since the driving method is set to 3 or more, the influence of the hysteresis characteristic peculiar to the polymer dispersion type liquid crystal panel is largely eliminated, and stable gradation control and contrast control are enabled. Further, since the liquid crystal display device of the present invention is provided with the temperature detecting means and the driving voltage correcting means, the driving voltage of the liquid crystal display device can be controlled in response to the fluctuation of the environmental temperature. It becomes possible to perform contrast control and gradation control corresponding to the temperature dependence of various characteristics (for example, applied voltage-transmittance characteristic, hysteresis characteristic, etc.), and stable and favorable display contrast and gradation expression can be realized.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a main part of an embodiment of the invention.

FIG. 2 is a diagram showing drive voltage waveforms according to an embodiment of the present invention.

FIG. 3 is a diagram showing an applied voltage-transmittance characteristic of a polymer-dispersed liquid crystal panel when driven by the drive voltage waveform of the present invention shown in FIG.

FIG. 4 is a diagram showing applied voltage ratio-display contrast index of the polymer dispersed liquid crystal panel when driven by the drive voltage waveform of the present invention shown in FIG.

FIG. 5 is an explanatory diagram (1) of hysteresis characteristics of the polymer-dispersed liquid crystal panel.

FIG. 6 is an explanatory diagram (No. 2) of hysteresis characteristics of the polymer-dispersed liquid crystal panel.

FIG. 7 is a diagram showing a structure of a polymer-dispersed liquid crystal panel.

FIG. 8 is a partially enlarged view of a polymer dispersed liquid crystal layer.

FIG. 9 is a diagram showing temperature dependence of applied voltage-transmittance characteristic and hysteresis characteristic of the polymer-dispersed liquid crystal panel.

[Explanation of symbols]

 10 Cell 11, 12 Transparent Substrate 13, 14 Transparent Electrode 15 Sealing Material 16 Polymer Dispersed Liquid Crystal Layer 17 Polymer 18 Liquid Crystal 20 Timing Generator 21 Gradation Modulator 22 Initialization Processor 23 Temperature Detector 24 Drive Voltage Corrector 25 Drive signal conversion unit 26 Liquid crystal display panel Ain Display signal input terminal Fc Initialization timing signal Fd Display timing signal Dc Initialization data Dk Digital voltage data Vh Driving voltage Vc Initialization voltage Vd Display pixel voltage T Driving cycle Tc Initialization period Td Display Data application period

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shuhei Yamamoto 1-8 Nakase, Nakase, Mihama-ku, Chiba-shi, Chiba Seiko Electronics Co., Ltd.

Claims (6)

[Claims] 1. In a liquid crystal display device having a liquid crystal layer between a pair of electrode substrates having at least one transparent electrode, an initialization voltage is applied at the beginning of each driving cycle, and thereafter,
A method of driving a liquid crystal display device, which comprises applying a pixel voltage corresponding to display data. 2. The method of driving a liquid crystal display device according to claim 1, wherein the initialization voltage is an applied voltage at which the light transmittance of the liquid crystal display device is substantially maximum. 3. The application time ratio of the application time of the initialization voltage and the application time of the display data is set such that the application time of the initialization voltage is 1 and the display data application time is 3 or more for each drive cycle. The method for driving a liquid crystal display device according to claim 1, wherein: 4. The method for driving a liquid crystal display device according to claim 1, 2 or 3, wherein the liquid crystal display device is a polymer dispersion type liquid crystal display device. 5. A liquid crystal display device having a liquid crystal layer between a pair of electrode substrates, at least one of which is provided with a transparent electrode, wherein the application time of the initialization voltage and the application time of the display data in each drive cycle are Timing generation means for controlling timing, gradation conversion means for converting an input display signal into digital voltage data, and initialization processing means for applying an initialization voltage at the beginning of each driving cycle. ,
Drive signal conversion means for converting the digital voltage data converted by the gradation conversion means or the initialization data output from the initialization processing means into a pixel voltage of a liquid crystal display panel, and an ambient temperature near the liquid crystal display panel And a drive voltage correction for correcting to a drive voltage corresponding to the temperature dependency of the applied voltage-transmittance characteristic of the liquid crystal display panel based on the temperature data output from the temperature detection means. A method of driving a liquid crystal display device, comprising: means for applying an initialization voltage at the beginning of each drive cycle, and thereafter applying a pixel voltage corresponding to display data. 6. The liquid crystal display device is a polymer-dispersed liquid crystal display device, and the initialization voltage is an applied voltage at which the light transmittance of the polymer-dispersed liquid crystal display device is substantially maximum. The method for driving the liquid crystal display device according to claim 5.