JPH06194625A - Driving method for ferroelectric liquid crystal display element - Google Patents

Abstract

PURPOSE:To make a clear gradational display on the active matrix type ferroelectric liquid crystal display element which uses non-memory type ferroelectric liquid crystal (DHF liquid crystal) having a spiral pitch smaller than a substrate interval. CONSTITUTION:In every selection period TS, a 1st reset voltage VR for orienting liquid crystal into a 1st orientation state and a 1st reset voltage -VR for orienting the liquid crystal into a 2nd orientation state are applied to the liquid crystal alternately in the same order as many time as each other, and then a write voltage VD is applied; before the 1st and 2nd reset voltages are applied, a compensating voltage -VD which has the opposite polarity from the write voltage VD and is equal in absolute value is applied.

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 ferroelectric liquid crystal display device.

[0002]

2. Description of the Related Art A ferroelectric liquid crystal display device using a ferroelectric liquid crystal has been noted for its high speed response and wide viewing angle as compared with a TN mode liquid crystal display device using a nematic liquid crystal. There is.

Research on the practical use of this ferroelectric liquid crystal display device has hitherto been made on a memory called an SS-F liquid crystal in which the helical pitch of the chiral smectic C phase is larger than the substrate gap (cell gap) of the display device and is aligned. It has been carried out for ferroelectric liquid crystals having properties (bistability).

The ferroelectric liquid crystal display device using the SS-F liquid crystal is one in which the SS-F liquid crystal is sealed between the substrates in a state where the helical structure is eliminated, and the spontaneous polarization of the liquid crystal with respect to an applied voltage causes The first alignment state when a voltage of one polarity is applied and the second alignment state when a voltage of the other polarity is applied.
The orientation state of the liquid crystal and the orientation state of the liquid crystal and the pair of polarizing plates arranged on the incident side and the emitting side of the device are used to control and display the light transmittance.

However, in the ferroelectric liquid crystal display element using the SS-F liquid crystal, the liquid crystal has only two alignment states, the first alignment state and the second alignment state, and even when no voltage is applied. Since either of the alignment states is maintained, it is difficult to change the transmittance and perform gradation display.

Therefore, recently, the development of a ferroelectric liquid crystal display device capable of displaying gray scales has been studied, and as one means therefor, the helical pitch of the chiral smectic C phase is smaller than the substrate spacing of the display device and the alignment state is improved. It has been proposed to use a ferroelectric liquid crystal having no memory property. The ferroelectric liquid crystal is called a DHF liquid crystal in distinction from the SS-F liquid crystal.

In the ferroelectric liquid crystal display element using the DHF liquid crystal, the DHF liquid crystal is enclosed between the substrates in a state of having a spiral structure, and the DHF liquid crystal is provided between electrodes facing each other with a liquid crystal layer in between. When a voltage equal to or higher than the threshold value is applied to the liquid crystal layer, the first alignment state or the second alignment state is aligned according to the polarity of the applied voltage, and a voltage lower than the threshold value is applied. Is oriented in a state in which both the first and second orientation states are mixed.

The DHF liquid crystal does not have the memory property of the alignment state like the SS-F liquid crystal, but the display element is an active matrix type in which a non-linear element such as TFT or MIM is an active element, and the non-selection period is set. It is said that gray scale display can be performed by holding a voltage that maintains the first and second alignment states and the alignment state in which both of them are mixed.

Conventionally, as a driving method for causing the ferroelectric liquid crystal display element to perform gradation display, a voltage for orienting the liquid crystal in either the first alignment state or the second alignment state in each selection period has been conventionally used. A method of applying a write voltage and then applying a write voltage has been considered.

[0010]

However, in the above-mentioned conventional driving method, the value of the write voltage and the transmittance do not correspond to each other, and therefore the gradation control is almost impossible, and the gradation display at the practical level is not possible. It could not be realized.

The present invention has a spiral pitch smaller than the distance between the substrates and, when a voltage equal to or higher than a threshold value is applied, one of the first alignment state and the second alignment state depending on the polarity of the applied voltage. Non-memory type ferroelectric liquid crystal (DH)
It is an object of the present invention to provide a driving method capable of causing an active matrix type ferroelectric liquid crystal display element using F liquid crystal) to perform clear gradation display.

[0012]

According to the driving method of the present invention, the voltage for orienting the liquid crystal in the first alignment state and the voltage for orienting the liquid crystal in the second alignment state are alternately the same number of times for each selection period. It is characterized in that the voltages are applied in order and then the write voltage is applied.

[0013]

In this driving method, since the voltage for orienting the liquid crystal in the first alignment state and the voltage for orienting the liquid crystal in the second alignment state are applied in the same order every selection period, the write voltage is applied. The alignment state of the liquid crystal immediately before is the same in any selection period. Therefore, since the value of the writing voltage and the transmittance correspond to each other, the transmittance is controlled by the writing voltage to realize a clear gradation display at a practical level. Can be realized.

In this driving method, the voltage for orienting the liquid crystal in the first alignment state and the voltage for orienting the liquid crystal in the second alignment state are alternately applied the same number of times for each selection period. There is no bias of electric charges between the electrodes, and therefore, a display burn-in phenomenon or liquid crystal deterioration does not occur.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

First, the structure of a ferroelectric liquid crystal display device driven for display by the driving method of the present invention will be described. FIG. 3 is a sectional view of a ferroelectric liquid crystal display device, and FIG. 4 is an equivalent circuit plan view of a substrate on which pixel electrodes and active devices of the liquid crystal display device are formed.

This ferroelectric liquid crystal display element is of an active matrix type, and of the pair of transparent substrates (eg glass substrates) 1 and 2, the lower substrate in FIG. 3 (hereinafter referred to as the lower substrate). 1, a transparent pixel electrode 3 and active elements 4 connected to the pixel electrode 3 are vertically and horizontally arranged.

The active element 4 is, for example, T
Although not shown, the structure of the TFT 4 is a FT (thin film transistor), a gate electrode formed on the substrate 1, a gate insulating film covering the gate electrode, and a semiconductor formed on the gate insulating film. And a source electrode and a drain electrode formed on the semiconductor layer.

Further, as shown in FIG. 4, on the lower substrate 1, gate lines 5 are arranged corresponding to the rows of the pixel electrodes 3 and data lines are arranged corresponding to the columns of the pixel electrodes 3. A line 6 is wired, the gate electrode of the TFT 4 is connected to the gate line 5, and the drain electrode is connected to the data line 6. In FIG. 4, 5a is a terminal portion of the gate line 5, and 6a is a terminal portion of the data line 6.

The gate line 5 is covered with the gate insulating film (transparent film) of the TFT 4 except the terminal portion 5a, and the data line 6 is formed on the gate insulating film. The pixel electrode 3 is formed on the gate insulating film and is connected to the source electrode of the TFT 4 at one end thereof.

On the other hand, in FIG. 3, a transparent counter electrode 7 facing the pixel electrodes 3 of the lower substrate 1 is formed on the upper substrate (hereinafter referred to as the upper substrate) 2. The counter electrode 7 is a single electrode having an area covering the entire display area.

Alignment films 8 and 9 are provided on the electrode forming surfaces of the lower substrate 1 and the upper substrate 2, respectively. Each of these alignment films 8 and 9 is a horizontal alignment film made of an organic polymer compound such as polyimide, and its film surface is subjected to an alignment treatment by rubbing.

The lower substrate 1 and the upper substrate 2 are adhered to each other via a frame-shaped sealing material 10 at the outer peripheral edge thereof and surrounded by the sealing material 10 between the two substrates 1 and 2. A ferroelectric liquid crystal (hereinafter referred to as DHF liquid crystal) 11 having a spiral pitch of the chiral smectic C phase smaller than the distance between the substrates 1 and 2 and having no memory property of the alignment state is enclosed in the region. In addition, in FIG.
Is a transparent gap material that regulates the distance between the substrates 1 and 2, and the gap material 12 is arranged in a scattered state in the liquid crystal enclosing region.

Since the spiral pitch of the DHF liquid crystal 11 is smaller than the distance between the substrates, the DHF liquid crystal 11 is enclosed between the substrates 1 and 2 in a spiral structure and faces the pixel electrode 3 which faces the liquid crystal layer. When a voltage equal to or higher than the threshold value is applied between the electrode 7 and the electrode 7, it is oriented in either the first orientation state or the second orientation state depending on the polarity of the applied voltage, and is lower than the threshold value. When a voltage is applied, it is oriented in a state in which both the first and second orientation states are mixed.

Further, a pair of polarizing plates 13 and 14 are arranged on the lower surface side and the upper surface side of the liquid crystal display element, and the direction of the transmission axis of these polarizing plates 13 and 14 is a threshold value between the electrodes 3 and 7. It is set according to the two alignment states of the DHF liquid crystal 11 when the above voltages are applied.

That is, FIG. 5 shows two alignment states of the DHF liquid crystal 11 when a voltage higher than the threshold value is applied and the directions of the transmission axes of the pair of polarizing plates 13 and 14 ( 3A shows the transmission axis 14a of the upper polarizing plate (hereinafter referred to as the upper polarizing plate) 14 in FIG. 3, and (b) shows the DHF.
Shows two alignment states 11a and 11b of the liquid crystal 11,
3C shows the transmission axis 13a of the lower polarizing plate (hereinafter referred to as the lower polarizing plate) 13 in FIG.

As shown in FIG. 5, the DHF liquid crystal 1 described above is used.
1 is a first alignment state 11a shown by a solid line when a voltage having one polarity and a voltage equal to or higher than the threshold voltage of the liquid crystal 11 is applied.
The second alignment state 1 shown by a broken line when a voltage having the other polarity and having a voltage equal to or higher than the threshold voltage of the liquid crystal 11 is applied.
Orient to 1b. The shift angle θ between the first alignment state 11a and the second alignment state 11b varies depending on the type of the DHF liquid crystal 11 and the surface energy of the alignment films 8 and 9, but the shift angle θ is about 45 °. It is desirable to choose.

Then, of the pair of polarizing plates 13 and 14, one polarizing plate, for example, the transmission axis 14a of the upper polarizing plate 14 is provided.
Are the two alignment states 11a and 11 of the DHF liquid crystal 11.
b, for example, is substantially parallel to the second alignment state 11b, and the transmission axis 13a of the other lower polarizing plate 13
Is substantially orthogonal to the transmission axis 14a of the upper polarizing plate 14.

The ferroelectric liquid crystal display element in which the transmission axis directions of the polarizing plates 13 and 14 are set as shown in FIG. 5 has the highest transmittance when the liquid crystal 11 is aligned in the first alignment state 11a ( The display becomes the brightest, and the transmittance becomes the lowest (the display becomes the darkest) when the liquid crystal 11 is aligned in the second alignment state 11b.

That is, the liquid crystal 11 has the first alignment state 11
In the state of being aligned in a, the linearly polarized light that has passed through one of the polarizing plates is subjected to the polarization effect of the liquid crystal 11 to become non-linearly polarized light.
Light of a certain polarized component of the light passes through the other polarizing plate and is emitted. Further, when the liquid crystal 11 is aligned in the second alignment state 11b, the linearly polarized light passing through one of the polarizing plates is hardly affected by the polarizing action of the liquid crystal 11 and is transmitted as it is through the liquid crystal layer, and Most of the light is absorbed by the other polarizing plate.

The DHF liquid crystal 11 is not limited to the two alignment states 11a and 11b, but the two alignment states 11a and 11b depending on the polarity and voltage value (absolute value) of the applied voltage.
11b is also oriented in a mixed state.

FIG. 6 shows a general voltage-transmittance characteristic (characteristic of change in light transmittance with respect to applied voltage) of the above-mentioned ferroelectric liquid crystal display element. The light transmittance of this ferroelectric liquid crystal display element is shown in FIG. , As shown in the figure, depending on the applied voltage.

Since this ferroelectric liquid crystal display element is of the active matrix type, the first and second alignment states 11 and 11b and the alignment state in which both the states are mixed are present even during the non-selection period. It is possible to hold the voltage for maintaining For this reason, it is said that the ferroelectric liquid crystal display device using the DHF liquid crystal can change the transmittance and display with gradation.

However, when the inventor conducted a drive test of the above-mentioned ferroelectric liquid crystal display device, it was almost impossible to control gradation by the drive method conventionally considered. Note that the conventional driving method is, as described in the section [Prior Art], applying a voltage for aligning the liquid crystal in either the first alignment state or the second alignment state for each selection period. In the drive test conducted by the inventor, a voltage for orienting the liquid crystal 11 in the first or second alignment state and a writing voltage having an absolute value smaller than that are alternately applied. Then, the change in transmittance was examined.

FIG. 7 is a waveform diagram of the gate signal and the data signal applied to the gate line 5 and the data line 6 of the liquid crystal display element in the above drive test, and the data signal brings the liquid crystal 11 into the first alignment state 11a. A reset pulse P1 with a voltage value to be oriented and a write pulse P2 with an arbitrary voltage value
And a reset pulse P3 having a voltage value for orienting the liquid crystal 11 in the second alignment state 11b and a write pulse P4 having an arbitrary voltage value different from the write pulse P2 are alternately repeated. In this drive test, the reference voltage of the data signal (the same voltage as the voltage applied to the counter electrode 7)
Was set to 0V.

The reset pulses P1 and P3 are applied to the history effect peculiar to the liquid crystal display element, that is, to the change of the alignment state of the liquid crystal when the write pulse is applied, the alignment state of the liquid crystal by the write pulse applied before (hereinafter , The previous state) is a pulse for resetting the effect of
When the reset pulses P1 and P3 are applied, the previous state when the write pulse is applied next is determined.

When the reset pulses P1 and P3 have the same polarity, the liquid crystal 11 is applied with a DC component more than the allowable value and the charge is deviated, which causes a display burn-in phenomenon and deterioration of the liquid crystal. For this reason, the P1 reset pulse and the P3 reset pulse are of opposite polarity. This is also the case with the conventional driving method, and in the conventional method, the polarities of the voltages for aligning the liquid crystal in the first or second alignment state are alternately reversed for each selection period.

8 and 9 show that the ferroelectric liquid crystal display device is driven by using the gate signal and the data signal having the above waveforms, and after applying the respective pulses P1, P2, P3 and P4. 8 shows the result of examining the average charge amount of spontaneous polarization of the liquid crystal 11 (corresponding to the average alignment state of the liquid crystal 11) and the transmittance, and FIG. 8 shows the writing pulse of P2 and P2.
Average charge amount of spontaneous polarization when voltage value of write pulse of 4 is 0V respectively (hereinafter referred to as average charge amount)
FIG. 9 shows the voltage value of the write pulse of P2 3.3.
The average charge amount and the transmittance of spontaneous polarization when the voltage values of the V and P4 write pulses are set to -3.3V are shown. In any case, the voltage values of the reset pulses P1 and P3 were set to P1 = 7.5V and P3 = -7.5V.

As can be seen from FIGS. 8 and 9, in the above drive test, the voltage values of the write pulses P2 and P4 did not correspond to the transmittance, so that gradation control was almost impossible.

That is, reproducible gradation display is possible if the transmissivities when the pulses of the same potential are applied as the write pulses P2 and P4 are the same, but in the drive test, as shown in FIG. Moreover, even if the potentials of the write pulses P2 and P4 are the same (here, P2 = P4 = 0V), the transmittance is completely different and there is no gradation reproducibility.

Further, in the above drive test, as shown in FIG. 9, even if pulses of different voltage values (here P2 = 3.3V, P4 = -3.3V) are applied as the write pulses P2 and P4, No clear difference in transmittance was obtained.

This is because the voltage-transmittance characteristic of the ferroelectric liquid crystal display element using the DHF liquid crystal has a hysteresis as shown in FIG. That is, the previous state when the P2 write pulse is applied is the first alignment state (actually, the first alignment state corresponds to the holding voltage of the capacitor formed by the pixel electrode 3, the counter electrode 7 and the liquid crystal 11 therebetween). (Orientation state close to the orientation state of P4) and the previous state at the time of applying the writing pulse of P4 is the second orientation state (orientation state close to the second orientation state). The voltage values of the pulses P2 and P4 do not correspond to the alignment state of the liquid crystal 11, that is, the transmittance.

Therefore, in the present invention, in order to obtain the transmittance corresponding to the value of the write voltage, the voltage for aligning the liquid crystal in the first alignment state and the alignment in the second alignment state are selected for each selection period. The driving method in which the applied voltage and the write voltage are applied in the same order alternately and the same number of times is adopted.

Explaining one embodiment of this driving method, FIG. 1 shows the waveforms of the gate signal and the data signal applied to the gate line 5 and the data line 6 connected to the TFT 4 of the first row of the ferroelectric liquid crystal display device. And the average charge amount of spontaneous polarization of the liquid crystal 11 and the transmittance.

In FIG. 1, TF is one frame period, T
S is the selection period of the TFT 4 in the first row, and TO is the non-selection period. In this embodiment, each selection period TS is equally divided into four slots t1, t2, t3, t4 and the final slot t4 thereof. Is the application period of the write pulse P14,
The first slot t1 is the application period of the compensation pulse P11 with respect to the write pulse P14.

Further, the other slots t2 and t3 are reset pulses (hereinafter referred to as first reset pulses) for aligning the liquid crystal 11 in the first alignment state 11a.
P12 and a reset pulse (hereinafter, referred to as a second reset pulse) P13 for aligning the liquid crystal 11 in the second alignment state 11b were applied. In addition, each pulse P11,
The application period (one slot time) of P12, P13 and P14 is about 45 μsec.

The compensation pulse P11 is the write pulse P14.
Is a pulse having a reverse polarity for compensating the bias of the DC component voltage applied to the liquid crystal 11 due to the application of the voltage.
Is the same as the voltage VD. The voltage VD of the write pulse P14 is controlled to various values according to the write data, and the voltage -VD of the compensation pulse P11 is also controlled correspondingly.

The second reset pulse P13 is a pulse for resetting the hysteresis effect of the liquid crystal display element, and the voltage value VR of the reset pulse P13 is a value sufficiently larger than the threshold voltage of the liquid crystal 11. The first reset pulse P12 is a reverse polarity pulse for compensating the bias of the DC component voltage applied to the liquid crystal 11 due to the application of the second reset pulse P13, and the voltage of the first reset pulse P12. -VR absolute value is the second reset pulse P1
It is the same as the voltage VR of 3.

Each of these pulses P11, P12, P13,
The polarity and voltage value of P14 are both the polarity and voltage of the data signal with respect to the reference voltage V0. This reference voltage V
0 is the same as the voltage applied to the counter electrode 7.

In this driving method, the write voltage V
The write voltage VD is controlled within the range of V0 to Vmax by setting the minimum value of D to V0 and the maximum value Vmax to a value slightly lower than the reset voltage VR of the second reset pulse P13.

When the ferroelectric liquid crystal display device is driven by using the gate signal and the data signal having the above waveforms,
For each selection period TS, the voltage of the compensation pulse P11 (hereinafter referred to as the write compensation voltage) -VD and the liquid crystal 11 are set to the first value.
Reset pulse P12 for orienting to the orientation state 11a of
Voltage (hereinafter, referred to as a first reset voltage) VR and a voltage of a second reset pulse P13 (hereinafter, referred to as a second reset voltage) -VR for aligning the liquid crystal 11 in the second alignment state-VR
And the voltage of the write pulse P14 (hereinafter referred to as write voltage) VD are sequentially applied to the pixel electrode 3 through the TFT 4, and accordingly, the average charge amount of spontaneous polarization and the transmittance of the liquid crystal 11 are respectively changed. It changes as shown in FIG.

When the non-selection period TO has passed after the selection period TS has passed, the TFT 4 is turned off, and a voltage corresponding to the write voltage VD applied to the final slot t4 of the selection period TS opposes the pixel electrode 3. Electrode 7 and liquid crystal 1 between them
Is held in the capacitor formed by 1 and, during the non-selection period To,
The average charge amount of spontaneous polarization and the transmittance of the liquid crystal 11 are maintained at a value corresponding to the holding voltage of the capacitance, that is, a value corresponding to the write voltage VD applied during the selection period TS.

In this driving method, the selection period TS
The first reset voltage VR for aligning the liquid crystal 11 to the first alignment state 11a and the liquid crystal 11 for the second alignment state 1a.
Since the second reset voltage -VR for orienting to 1b is applied in the same order, the alignment state of the liquid crystal 11 immediately before the writing voltage VD is applied is the same in any selection period TS (in this embodiment, the second reset voltage -VR). Since it is in the alignment state 11b), and therefore the value of the write voltage VD corresponds to the transmittance,
The transmittance can be controlled by the writing voltage VD to realize clear gradation display at a practical level.

That is, as shown in FIG. 1, for example, assuming that the liquid crystal 11 is in a certain alignment state (alignment state according to the write voltage applied previously), the write voltage VD applied in the next selection period TS is reset. Assuming that the voltage is 1/2 the voltage VR, the average charge amount of spontaneous polarization of the liquid crystal 11 in the non-selection period TO after applying the write voltage VD (VD = VR / 2) becomes almost zero. The alignment states of the liquid crystal 11 at this time are the first alignment state 11a and the second alignment state 1
1b and the liquid crystal 11 are mixed in substantially the same proportion, and therefore, the transmittance is the highest when the liquid crystal 11 is aligned in the first alignment state 11a and the liquid crystal 11 is in the second alignment state 11b. The value is almost halfway between the lowest transmittance when oriented.

Further, as shown in FIG. 1, the selection period T
Assuming that the write voltage VD applied in the next selection period TS of S is one fourth of the reset voltage VR, the liquid crystal in the non-selection period TO after application of the write voltage VD (VD = VR / 4). The average charge amount of the spontaneous polarization of 11 becomes a value in which the negative charge component is larger than the above-mentioned charge amount of almost zero. The alignment state of the liquid crystal 11 at this time is a state in which the first alignment state 11a and the second alignment state 11b are mixed in a larger proportion in the second alignment state 11b, and therefore the transmittance is higher. Is a value between the lowest transmittance and the intermediate transmittance when the liquid crystal 11 is aligned in the second alignment state 11b.

This is the same when the write voltage VD of another voltage is applied. For example, when the minimum voltage V0 is applied as the write voltage VD, as shown by the chain double-dashed line in FIG. The average charge amount of the spontaneous polarization of the liquid crystal 11 is a value in which the most negative charge component in the control range is the largest, that is, a value close to the charge amount when the liquid crystal 11 is aligned in the second alignment state 11b. And the transmittance becomes the lowest value in the control range.

When the maximum voltage Vmax is applied as the write voltage VD, the average charge amount of the spontaneous polarization of the liquid crystal 11 is the highest in the control range, as shown by the three-dot chain line in FIG. The value has the largest number of positive charge components, that is, a value close to the amount of charge when the liquid crystal 11 is aligned in the first alignment state 11a, and the transmittance has the highest value in the control range. .

As described above, according to the above driving method, the transmittance corresponding to the value of the writing voltage VD can be obtained. Therefore, by controlling the transmittance by the writing voltage VD, clear gradation display at a practical level can be achieved. Can be realized.

This is because the alignment state of the liquid crystal 11 immediately before the write voltage VD is applied is the same (the second alignment state 11b in this embodiment) in any selection period TS, and the write voltage VD is If the alignment state of the liquid crystal 11 before application is always the same, the hysteresis of the voltage-transmittance characteristic of the ferroelectric liquid crystal display element using the DHF liquid crystal does not appear in the operation, so that the value of the write voltage VD becomes A corresponding transmission is obtained.

That is, FIG. 2 is a voltage-transmittance characteristic diagram when the ferroelectric liquid crystal display device is driven by the driving method of the above-mentioned embodiment. As shown in FIG. The voltage-transmittance characteristic has no hysteresis.

The voltage-transmittance characteristic shown in FIG.
This is the characteristic when the reference voltage VO of the data signal is 8 V (the voltage applied to the counter electrode 7 is also the same). In this case,
The first reset voltage VR is 10 V or more (preferably 11 V
V or more), the second reset voltage -VR is 6 V or less (preferably 5 V or less), and the write voltage VD is about 6.5 V or more.
It may be controlled in the range of about 10.5V.

In the above driving method, the first reset voltage VR for aligning the liquid crystal 11 to the first alignment state 11a and the liquid crystal 11 for the second alignment state 11b are selected every selection period TS.
Since the second reset voltage −VR for orienting in the same direction is alternately applied at the same number of times (once in the above embodiment),
A direct current component equal to or more than the allowable value does not deviate to the liquid crystal 11 in a biased manner, and therefore a display burn-in phenomenon or deterioration of the liquid crystal does not occur.

In the above embodiment, the reset voltage VR
, -VR are applied in the order of the first reset voltage VR and the second reset voltage -VR. The reset voltage VR,
The application order of -VR may be reversed, and the reset voltages VR and -VR are almost the same for the liquid crystal 11 as the first and second reset voltages.
As long as the voltage is oriented to the alignment states 11a and 11b, the voltage need not be completely aligned to the alignment states 11a and 11b.

In the above embodiment, the first reset voltage VR and the second reset voltage -VR are applied once, but the number of times these reset voltages VR, -VR are applied may be arbitrary. , The first reset voltage VR and the second reset voltage −VR may be alternately applied at the same number of times.

Further, in the ferroelectric liquid crystal display device driven in the above embodiment, the transmission axis 14a of one polarizing plate 14 is DH.
Although the second alignment state 11b of the F liquid crystal 11 is made substantially parallel, the above-mentioned driving method makes the transmission axis 14a of one polarizing plate 14 substantially parallel to the first alignment state 11a of the DHF liquid crystal 11. , The transmittance is highest when the liquid crystal 11 is aligned in the second alignment state 11b (the display is brightest), and the transmittance is lowest when the liquid crystal 11 is aligned in the first alignment state 11a ( It can also be applied to drive a ferroelectric liquid crystal display device in which the display becomes darkest.
The invention can be applied not only to the one using the TFT as the active element but also to the driving of the ferroelectric liquid crystal display element using the MIM as the active element.

[0066]

According to the driving method of the present invention, the selection period
Since the voltage for orienting the liquid crystal in the first alignment state and the voltage for orienting the liquid crystal in the second alignment state are alternately applied in the same order by the same number of times and then the write voltage is applied, a spiral smaller than the substrate spacing is applied. A non-memory type ferroelectric liquid crystal that has a pitch and that is aligned in one of a first alignment state and a second alignment state depending on the polarity of the applied voltage when a voltage of a threshold value or more is applied ( An active matrix type ferroelectric liquid crystal display element using DHF liquid crystal) can display clear gradation.

[Brief description of drawings]

FIG. 1 is a diagram showing waveforms of a gate signal and a data signal, and an average charge amount and a transmittance of spontaneous polarization of liquid crystal according to an embodiment of the present invention.

FIG. 2 is a voltage-transmittance characteristic diagram when a ferroelectric liquid crystal display element is driven by the driving method of the example.

FIG. 3 is a sectional view of a ferroelectric liquid crystal display element.

FIG. 4 is an equivalent circuit plan view of a substrate on which pixel electrodes and active elements are formed.

FIG. 5 is a diagram showing two alignment states of DHF liquid crystal and directions of transmission axes of a pair of polarizing plates.

FIG. 6 is a general voltage-transmittance characteristic diagram of a ferroelectric liquid crystal display device.

FIG. 7 is a waveform diagram of a gate signal and a data signal applied in a drive test by a conventional drive method performed by the inventor.

FIG. 8 is a diagram showing a spontaneous polarization average charge amount and a transmittance of a liquid crystal when a drive test is performed with a voltage value of a write pulse set to 0V.

FIG. 9 shows the voltage value of the write pulse at 3.3V and -3.3V.
FIG. 6 is a diagram showing the spontaneous polarization average charge amount and the transmittance of the liquid crystal when the drive test is performed in the above manner.

[Explanation of symbols]

 3 ... Pixel electrode 4 ... Active element (TFT) 7 ... Counter electrode 8, 9 ... Alignment film 11 ... DHF liquid crystal 11a ... 1st alignment state 11b ... 2nd alignment state 13, 14 ... Polarizing plate 13a, 14a ... Transmission Axis P11 ... Compensation pulse P12, P13 ... Reset pulse VR, -VR ... Reset voltage P14 ... Write pulse VD ... Write voltage

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[Procedure amendment]

[Submission date] August 9, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Driving method for ferroelectric liquid crystal display device

[Claims]

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 ferroelectric liquid crystal display device.

[0002]

2. Description of the Related Art A ferroelectric liquid crystal display device using a ferroelectric liquid crystal has been noted for its high speed response and wide viewing angle as compared with a TN mode liquid crystal display device using a nematic liquid crystal. There is.

Research on the practical use of this ferroelectric liquid crystal display device has hitherto been made on a memory called an SS-F liquid crystal in which the helical pitch of the chiral smectic C phase is larger than the substrate gap (cell gap) of the display device and is aligned. It has been carried out for ferroelectric liquid crystals having properties (bistability).

The ferroelectric liquid crystal display device using the SS-F liquid crystal is one in which the SS-F liquid crystal is sealed between the substrates in a state where the helical structure is eliminated, and the spontaneous polarization of the liquid crystal with respect to an applied voltage causes The first alignment state when a voltage of one polarity is applied and the second alignment state when a voltage of the other polarity is applied.
The orientation state of the liquid crystal and the orientation state of the liquid crystal and the pair of polarizing plates arranged on the incident side and the emitting side of the device are used to control and display the light transmittance.

However, in the ferroelectric liquid crystal display element using the SS-F liquid crystal, the liquid crystal has only two alignment states, the first alignment state and the second alignment state, and even when no voltage is applied. Since either of the alignment states is maintained, it is difficult to change the transmittance and perform gradation display.

Therefore, recently, the development of a ferroelectric liquid crystal display device capable of gradation display has been studied, and "LIQUID CRY"
STALS 1989, Vol. 5, 1171-1177 ”
As described above, it has been proposed to use a ferroelectric liquid crystal in which the helical pitch of the chiral smectic C phase is smaller than the substrate spacing of the display element and does not have the memory property of the alignment state.
The ferroelectric liquid crystal is called a DHF liquid crystal in distinction from the SS-F liquid crystal.

In the ferroelectric liquid crystal display element using the DHF liquid crystal, the DHF liquid crystal is enclosed between the substrates in a state of having a spiral structure, and the DHF liquid crystal is provided between electrodes facing each other with a liquid crystal layer in between. Depending on the voltage applied to the liquid crystal
A first alignment state in which molecules are substantially aligned in one direction,
A second orientation state in which crystal molecules are substantially aligned in the other direction,
And the average of the liquid crystal molecules due to the distortion of the helical structure of the molecular arrangement
A different alignment direction between the first alignment state and the second alignment state.
It is oriented to any intermediate orientation state.

[0008] The DHF liquid crystal is the intermediate device described above.
Since the desired alignment state can be obtained, it does not have the memory property of the alignment state as in the above SS-F liquid crystal, but the display element is an active matrix type in which a nonlinear element such as a TFT or MIM is an active element. It is said that gradation display is possible by holding the voltage for maintaining the above-mentioned arbitrary alignment state during the selection period.

[0009] As a driving method to perform gradation display on the ferroelectric liquid crystal display device, conventionally, for each selection period, the table
A method of applying a write voltage having a voltage according to the data to be shown has been considered.

[0010]

However, in the above-mentioned conventional driving method, the value of the write voltage and the transmittance do not correspond to each other, and therefore the gradation control is almost impossible, and the gradation display at the practical level is not possible. It could not be realized.

The present invention has a non-memory type ferroelectric having a spiral pitch smaller than a substrate interval and orienting into a first orientation state, a second orientation state and an intermediate orientation state according to an applied voltage. It is an object of the present invention to provide a driving method capable of causing an active matrix type ferroelectric liquid crystal display element using an active liquid crystal (DHF liquid crystal) to perform clear gradation display.

[0012]

The driving method of the present invention According to an aspect of the, D
In a ferroelectric liquid crystal display element using HF liquid crystal,
A voltage is applied to the ferroelectric liquid crystal to control its alignment state.
Liquid crystal molecules in the first alignment state for each selection period
Arranged in at least one of the first and second alignment states
An initialization voltage was applied, and this initialization voltage was applied.
It is characterized in that a write voltage according to data to be displayed later is applied. Then, the initialization voltage is
The liquid crystal molecules are aligned in the first alignment state while the polar first
Reset pulse and align the liquid crystal molecules to the second alignment state
The second reset pulse to
And the voltage is continuous in the same order. Also the first reset
And the second reset pulse have opposite polarities.
Are set to voltages with the same absolute value. Furthermore, this
In the driving method of Ming, in each selection period, during the selection period
And applied during the selection period before the initialization voltage is applied.
Compensation voltage whose polarity is opposite to that of the written voltage and whose absolute value is equal
Is applied.

[0013]

In this driving method, the transmittance of the liquid crystal display device is maximized.
Liquid crystal components corresponding to the low state and the highest state, respectively.
The orientation of the child, that is, the lesser of the first and second orientations.
Initialization to align liquid crystal molecules in one orientation state, even if not
After applying the voltage, write the write voltage according to the display data.
As a result, the hysteresis of DHF liquid crystal is increased.
The write voltage value is
It is possible to make a one-to-one correspondence between the transmittance and the transmittance, and display a clear gradation.

Further, in this driving method, the liquid crystal molecules are first
The first reset pulse having one polarity while being oriented in the
And a second re-alignment for orienting the liquid crystal molecules to the second alignment state.
Set pulse and sequence in the same order for each selection period.
The initializing voltage applied to the first reset
And the second reset pulse has opposite polarities and is absolute
Since the voltages are set to the same value, the initialization voltage is applied.
As a result, electric charges are not biased between the opposing electrodes. Furthermore
In this driving method, during each selection period, during the selection period
And before the reset voltage is applied during the selection period.
Compensation voltage with reverse polarity and equal absolute value to the applied write voltage.
Since a pressure is applied, the electrodes facing each other depending on the write voltage
There is no bias in the charge between them. Therefore , the phenomenon of display burn-in and deterioration of the liquid crystal do not occur , and the clear floor
The key display can be performed.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

First, the structure of a ferroelectric liquid crystal display device driven for display by the driving method of the present invention will be described. FIG. 3 is a sectional view of a ferroelectric liquid crystal display device, and FIG. 4 is an equivalent circuit plan view of a substrate on which pixel electrodes and active devices of the liquid crystal display device are formed.

This ferroelectric liquid crystal display element is of an active matrix type, and of the pair of transparent substrates (eg glass substrates) 1 and 2, the lower substrate in FIG. 3 (hereinafter referred to as the lower substrate). 1, a transparent pixel electrode 3 and active elements 4 connected to the pixel electrode 3 are vertically and horizontally arranged.

The active element 4 is, for example, T
Although not shown, the structure of the TFT 4 is a FT (thin film transistor), a gate electrode formed on the substrate 1, a gate insulating film covering the gate electrode, and a semiconductor formed on the gate insulating film. And a source electrode and a drain electrode formed on the semiconductor layer.

Further, as shown in FIG. 4, on the lower substrate 1, gate lines 5 are arranged corresponding to the rows of the pixel electrodes 3 and data lines are arranged corresponding to the columns of the pixel electrodes 3. A line 6 is wired, the gate electrode of the TFT 4 is connected to the gate line 5, and the drain electrode is connected to the data line 6. In FIG. 4, 5a is a terminal portion of the gate line 5, and 6a is a terminal portion of the data line 6.

The gate line 5 is covered with the gate insulating film (transparent film) of the TFT 4 except the terminal portion 5a, and the data line 6 is formed on the gate insulating film. The pixel electrode 3 is formed on the gate insulating film and is connected to the source electrode of the TFT 4 at one end thereof.

On the other hand, in FIG. 3, a transparent counter electrode 7 facing the pixel electrodes 3 of the lower substrate 1 is formed on the upper substrate (hereinafter referred to as the upper substrate) 2. The counter electrode 7 is a single electrode having an area covering the entire display area.

Alignment films 8 and 9 are provided on the electrode forming surfaces of the lower substrate 1 and the upper substrate 2, respectively. Each of these alignment films 8 and 9 is a horizontal alignment film made of an organic polymer compound such as polyimide, and its film surface is subjected to an alignment treatment by rubbing.

The lower substrate 1 and the upper substrate 2 are adhered to each other via a frame-shaped sealing material 10 at the outer peripheral edge thereof and surrounded by the sealing material 10 between the two substrates 1 and 2. A ferroelectric liquid crystal (hereinafter referred to as DHF liquid crystal) 11 having a spiral pitch of the chiral smectic C phase smaller than the distance between the substrates 1 and 2 and having no memory property of the alignment state is enclosed in the region. This DHF liquid crystal has
The spiral pitch of the spiral structure has a wavelength in the visible light band (400 nm ~
700 nm) or less, for example, a spiral pitch of 300 nm to 40
0 nm, large spontaneous polarization, cone angle
Of about 27 ° is a ferroelectric liquid crystal composition. In FIG. 3, reference numeral 12 is a transparent gap member that regulates the distance between the substrates 1 and 2, and the gap members 12 are arranged in a scattered state in the liquid crystal enclosing region.

The DHF liquid crystal 11 has a smectic characteristic.
The normal direction of the layer of the layer structure of the C phase is
Towards the direction regulated by the alignment treatment of the alignment films 8 and 9
Since a uniform layer structure is formed and the spiral pitch is smaller than the substrate interval , the layers are enclosed between the substrates 1 and 2 in a spiral structure . And this DHF liquid crystal 1
1 indicates that when a voltage higher than a predetermined value is applied between the pixel electrode 3 and the counter electrode 7 that face each other across the liquid crystal layer ,
A first alignment state in which liquid crystal molecules are aligned in one direction and a second alignment state in which liquid crystal molecules are aligned in the other direction depending on the polarity of the applied voltage .
When the liquid crystal layer is aligned in any one of the above two states and a low intermediate voltage is applied , the helical structure of the DHF liquid crystal 11 is
By distorting, the average alignment direction of liquid crystal molecules is applied.
In the first and second alignment states depending on the value of the voltage
The liquid crystal molecules are aligned in the middle direction.

Further, a pair of polarizing plates 13 and 14 are arranged on the lower surface side and the upper surface side of the liquid crystal display element, and the direction of the transmission axis of these polarizing plates 13 and 14 has a polarity between the electrodes 3 and 7.
Conversely, the DHF liquid crystal 11 when a voltage with a high absolute value is applied
Are set according to the two orientation states of.

That is, FIG. 5 shows two alignment states of the DHF liquid crystal 11 and a direction of the transmission axes of the pair of polarizing plates 13 and 14 when a voltage of a predetermined value or more is applied. 3A shows the transmission axis 14a of the upper polarizing plate (hereinafter referred to as the upper polarizing plate) 14 in FIG. 3, and (b) shows the DHF.
The alignment directions 11a and 11b of the liquid crystal molecules in the two alignment states of the liquid crystal 11 are shown, and (c) shows the transmission axis 13a of the lower polarizing plate (hereinafter referred to as the lower polarizing plate) 13 in FIG.

As shown in FIG. 5, the DHF liquid crystal 1 described above is used.
1 is a first alignment state when a voltage of one polarity and a voltage equal to or higher than a predetermined value is applied, and the first alignment method shown by a solid line
The liquid crystal molecules are oriented in the direction 11a . When a voltage having the other polarity and a voltage equal to or higher than a predetermined value is applied, the second orientation
On purpose made, liquid crystal molecules in the second alignment direction 11b indicated by the dashed line
There oriented. The deviation angle θ between the first alignment direction 11a and the second alignment direction 11b differs depending on the type of the DHF liquid crystal 11, the surface energy of the alignment films 8 and 9, and the like.
It is desirable to select this deviation angle θ to be about 45 °.

Then, of the pair of polarizing plates 13 and 14, one polarizing plate, for example, the transmission axis 14a of the upper polarizing plate 14 is provided.
Are the two alignment directions 11a and 11 of the DHF liquid crystal 11.
b, for example, is substantially parallel to the second alignment direction 11b, and the transmission axis 13a of the other lower polarizing plate 13
Is substantially orthogonal to the transmission axis 14a of the upper polarizing plate 14.

The ferroelectric liquid crystal display element in which the transmission axis directions of the polarizing plates 13 and 14 are set as shown in FIG. 5 has the highest transmittance when the liquid crystal 11 is oriented in the first orientation direction 11a ( The display becomes brightest), and the liquid crystal 11 is aligned in the second orientation.
When oriented in the direction 11b, the transmittance is lowest (display is darkest).

That is, the liquid crystal molecules have the first alignment direction 11
In the state of being aligned in a, the linearly polarized light that has passed through the polarizing plate on the incident side is polarized by the liquid crystal 11 to become non-linearly polarized light, and a component parallel to the optical axis of the polarizing plate on the outgoing side is also included.
The emitted light passes through the emission side polarization plate and is emitted. Also,
When the liquid crystal molecules are aligned in the second alignment direction 11b,
The linearly polarized light that has passed through the polarizing plate on the incident side passes through the liquid crystal layer as linearly polarized light with almost no polarization effect by the liquid crystal 11, and most of the light is absorbed by the polarizing plate on the outgoing side .

Further, the DHF liquid crystal 11, the two alignment directions 11a, 11b as well as the polarity and the voltage value of the applied voltage the two alignment directions 11a according to (the absolute value),
It is also oriented in the intermediate state of 11b.

[0032] Figure 6 is voltage of the ferroelectric liquid crystal display device -
The transmittance characteristics (change characteristics of light transmittance with respect to applied voltage) are shown, and the light transmittance of this ferroelectric liquid crystal display element is
It changes as shown depending on the applied voltage.

Since this ferroelectric liquid crystal display element is of the active matrix type, it is possible to hold the voltage for maintaining the DHF liquid crystal 11 in the intermediate alignment state even during the non-selection period. Thus, a ferroelectric liquid crystal display device using a DHF liquid crystal, Ru can der thereby the transmittance is varied by performing the display with a gray scale.

However, when the inventor conducted a drive test of the ferroelectric liquid crystal display device, it was found that the gradation could not be controlled.
It was. In the drive test conducted by the inventor, a change in transmittance was examined by alternately applying a voltage for orienting the liquid crystal 11 in the first or second alignment state and a writing voltage having an absolute value smaller than that. .

FIG. 7 is a waveform diagram of a gate signal and a data signal applied to the gate line 5 and the data line 6 of the liquid crystal display element in the above drive test. The data signal indicates that the liquid crystal 11 is directed in the first alignment direction 11a. A reset pulse P1 with a voltage value to be oriented and a write pulse P2 with an arbitrary voltage value
And a reset pulse P3 having a voltage value for aligning the liquid crystal 11 in the second alignment direction 11b and a writing pulse P4 having an arbitrary voltage value are alternately repeated. In this drive test, the reference voltage of the data signal (the same voltage as the voltage applied to the counter electrode 7) was set to 0V.

The reset pulses P1 and P3 are applied to the history effect peculiar to the liquid crystal display element, that is, to the change of the alignment state of the liquid crystal when the write pulse is applied, the alignment state of the liquid crystal by the write pulse applied before (hereinafter , The previous state) is a pulse for resetting the effect of
When the reset pulses P1 and P3 are applied, the previous state when the write pulse is applied next is determined.

When the reset pulses P1 and P3 have the same polarity, the liquid crystal 11 is applied with a DC component more than the allowable value and the charge is deviated, which causes a display burn-in phenomenon and deterioration of the liquid crystal. Therefore, P1 reset pulse and P3 reset pulse have opposite polarity.
It was

8 and 9 show that the ferroelectric liquid crystal display device is driven by using the gate signal and the data signal having the above waveforms, and after applying the respective pulses P1, P2, P3 and P4. 8 shows the results of examining the average charge amount (corresponding to the average alignment state of the liquid crystal 11) and the transmittance due to the spontaneous polarization of the liquid crystal 11, and FIG. 8 shows the writing pulse of P2 and the writing pulse of P4. The average charge amount (hereinafter, referred to as the average charge amount) and the transmittance due to spontaneous polarization when the voltage values of P2 and P4 are set to 0 V, respectively. Voltage value is -3.3V
The average charge amount and the transmittance due to spontaneous polarization are shown. In either case, the reset pulse P1
, P3 voltage values are P1 = 7.5V, P3 = -7.5V
And

As can be seen from FIGS. 8 and 9, in the above drive test, the voltage values of the write pulses P2 and P4 do not correspond to the transmittance, so that the gradation can be controlled.
Didn't come

That is, reproducible gradation display is possible if the transmissivities when the pulses of the same potential are applied as the write pulses P2 and P4 are the same, but in the drive test, as shown in FIG. Moreover, even if the potentials of the write pulses P2 and P4 are the same (here, P2 = P4 = 0V), the transmittance is completely different and there is no gradation reproducibility.

Further, in the above drive test, as shown in FIG. 9, even if pulses having different voltage values (here, P2 = 3.3V, P4 = -3.3V) are applied as the write pulses P2 and P4, No clear difference in transmittance was obtained.

This is because the voltage-transmittance characteristic of the ferroelectric liquid crystal display element using the DHF liquid crystal has a hysteresis as shown in FIG. That is, the previous state when the P2 write pulse is applied is the first alignment state (actually, the first alignment state corresponds to the holding voltage of the capacitor formed by the pixel electrode 3, the counter electrode 7 and the liquid crystal 11 therebetween). (Orientation state close to the orientation state of P4) and the previous state at the time of applying the writing pulse of P4 is the second orientation state (orientation state close to the second orientation state). The voltage values of the pulses P2 and P4 do not correspond to the alignment state of the liquid crystal 11, that is, the transmittance.

Therefore, in the present invention, in order to obtain the transmittance corresponding to the value of the write voltage, the voltage for orienting the liquid crystal in the first alignment state and the second voltage for each selection period are set.
The same number as the voltage for orienting each
A driving method is adopted in which an initialization voltage which is continuously applied is applied alternately, and this initialization voltage is applied, and then a writing voltage according to data to be displayed is applied.

Explaining one embodiment of this driving method, FIG. 1 shows the waveforms of the gate signal and the data signal applied to the gate line 5 and the data line 6 connected to the TFT 4 of the first row of the ferroelectric liquid crystal display device. And the spontaneous polarization of the liquid crystal 11.
Therefore, the average charge amount and the transmittance are shown.

In FIG. 1, TF is one frame period, T
S is the selection period of the TFT 4 in the first row, and TO is the non-selection period. In this embodiment, each selection period TS is equally divided into four slots t1, t2, t3, t4 and the final slot t4 thereof. Is the application period of the write pulse P14,
The first slot t1 is the application period of the compensation pulse P11 with respect to the write pulse P14.

Further, the other slots t2 and t3 respectively have a reset pulse (hereinafter, referred to as a first reset pulse) P12 for aligning the liquid crystal 11 in the first alignment state.
And a reset pulse (hereinafter, referred to as a second reset pulse) P13 for aligning the liquid crystal 11 in the second alignment state is applied , and these reset pulses P12 and P13 are used.
Configured the initialization voltage. In addition, each of the pulses P11, P
The application period (one slot time) of 12, P13 and P14 is approximately 45 μsec.

The compensation pulse P11 is the write pulse P14.
Is a pulse having a reverse polarity for compensating the bias of the DC component voltage applied to the liquid crystal 11 due to the application of the voltage.
Is the same as the voltage VD. The voltage VD of the write pulse P14 is controlled to various values according to the write data, and the voltage -VD of the compensation pulse P11 is also controlled correspondingly.

The second reset pulse P13 is a pulse for eliminating the influence of the hysteresis of the liquid crystal display element, and the voltage value VR of the reset pulse P13 is the liquid crystal 11
The value is large enough for most of the molecules of to arrange in a certain direction . The first reset pulse P12 is a reverse polarity pulse for compensating the bias of the DC component voltage applied to the liquid crystal 11 due to the application of the second reset pulse P13. The voltage of the first reset pulse P12 -VR
Has the same absolute value as the voltage VR of the second reset pulse P13.

Each of these pulses P11, P12, P13,
The polarity and voltage value of P14 are both the polarity and voltage of the data signal with respect to the reference voltage V0. This reference voltage V
0 is the same as the voltage applied to the counter electrode 7.

In this driving method, the write voltage V
The write voltage VD is controlled within the range of V0 to Vmax by setting the minimum value of D to V0 and the maximum value Vmax to a value slightly lower than the reset voltage VR of the second reset pulse P13.

When the ferroelectric liquid crystal display device is driven by using the gate signal and the data signal having the above waveforms,
For each selection period TS, the voltage of the compensation pulse P11 (hereinafter referred to as the write compensation voltage) -VD and the liquid crystal 11 are set to the first value.
Reset pulse P12 for orienting in the orientation direction 11a of
(Hereinafter referred to as the first reset voltage) VR and the voltage of the second reset pulse P13 (hereinafter referred to as the second reset voltage) for orienting the liquid crystal 11 in the second orientation direction 11b-
VR and the voltage of the write pulse P14 (hereinafter referred to as write voltage) VD are sequentially applied to the pixel electrode 3 through the TFT 4, and along with this, an average charge amount due to spontaneous polarization of the liquid crystal 11 and The transmittance changes as shown in FIG.

When the non-selection period TO has passed after the selection period TS has passed, the TFT 4 is turned off, and a voltage corresponding to the write voltage VD applied to the final slot t4 of the selection period TS opposes the pixel electrode 3. Electrode 7 and liquid crystal 1 between them
Is held in the capacitor formed by 1 and, during the non-selection period To,
The average charge amount and the transmittance due to the spontaneous polarization of the liquid crystal 11 are values corresponding to the holding voltage of the capacitance, that is, the selection period TS
It is maintained at a value according to the write voltage VD applied to.

In this driving method, the selection period TS
The first reset voltage VR for orienting the liquid crystal 11 in the first orientation direction 11a, and the second orientation direction 1 for the liquid crystal 11.
Since the second reset voltage -VR for orienting to 1b is applied in the same order, the alignment state of the liquid crystal 11 immediately before the writing voltage VD is applied is the same in any selection period TS (in this embodiment, the second reset voltage -VR). an alignment direction 11b), above
It is not affected by the hysteresis. Therefore, since the value of the writing voltage VD and the transmittance correspond to each other, the transmittance can be controlled by the writing voltage VD to realize clear gradation display at a practical level.

That is, as shown in FIG. 1, for example, assuming that the liquid crystal 11 is in a certain alignment state (alignment state according to the write voltage applied previously), the write voltage VD applied in the next selection period TS is reset. Assuming that the voltage is 1/2 the voltage VR, the average charge amount of spontaneous polarization of the liquid crystal 11 in the non-selection period TO after applying the write voltage VD (VD = VR / 2) becomes almost zero. The alignment state of the liquid crystal 11 at this time is intermediate between the first alignment state and the second alignment state.
The average alignment direction of liquid crystal molecules is the first
And the central direction of the second alignment directions 11a and 11b.
Therefore, the transmittance is such that the liquid crystal molecules have the first alignment direction 11
The value is almost halfway between the highest transmittance when the liquid crystal molecules are aligned in a and the lowest transmittance when the liquid crystal molecules are aligned in the second alignment direction 11b.

Further, as shown in FIG. 1, the selection period T
Assuming that the write voltage VD applied in the next selection period TS of S is one fourth of the reset voltage VR, the liquid crystal in the non-selection period TO after application of the write voltage VD (VD = VR / 4). The average charge amount due to the spontaneous polarization of 11 becomes a value in which the negative charge component is larger than the above-mentioned charge amount of almost zero. Orientation of the liquid crystal 11 in this case, an intermediate alignment state der the first orientation shaped on purpose second alignment direction state
The average alignment direction of liquid crystal molecules is the second alignment direction 1.
The direction is offset to 1b. Therefore, the transmittance is a value between the lowest transmittance when the liquid crystal molecules are aligned in the second alignment direction 11b and the intermediate transmittance.

This is the same when the write voltage VD of another voltage is applied. For example, when the minimum voltage V0 is applied as the write voltage VD, as shown by the chain double-dashed line in FIG. The average charge amount due to spontaneous polarization of the liquid crystal 11 is
The most negative charge component in the control range is the largest value, that is, the value is close to the charge amount when the liquid crystal molecules are aligned in the second alignment direction 11b, and the transmittance is within the control range. It is the lowest of them.

When the maximum voltage Vmax is applied as the write voltage VD, the average charge amount due to the spontaneous polarization of the liquid crystal 11 is the highest in the control range, as shown by the three-dot chain line in FIG. The value has the largest number of positive charge components, that is, a value close to the amount of charge when the liquid crystal molecules are aligned in the first alignment direction 11a, and the transmittance has the highest value in the control range. .

As described above, according to the above driving method, since the transmittance corresponding to the value of the writing voltage VD is obtained, the transmittance can be controlled by the writing voltage VD to realize a clear gradation display. it can.

This is because the alignment state of the liquid crystal 11 just before the write voltage VD is applied is the same (the second alignment direction 11b in this embodiment) in any selection period TS, and the write voltage VD is If the alignment state of the liquid crystal 11 before application is always the same, the hysteresis of the voltage-transmittance characteristic of the ferroelectric liquid crystal display element using the DHF liquid crystal does not appear in the operation, so that the value of the write voltage VD becomes A corresponding transmission is obtained.

That is, FIG. 2 is a voltage-transmittance characteristic diagram when the ferroelectric liquid crystal display device is driven by the driving method of the above-mentioned embodiment. As shown in FIG. The voltage-transmittance characteristic has no hysteresis.

The voltage-transmittance characteristic shown in FIG.
This is the characteristic when the reference voltage VO of the data signal is 8 V (the voltage applied to the counter electrode 7 is also the same). In this case,
The first reset voltage VR is 10 V or more (preferably 11 V
V or more), the second reset voltage -VR is 6 V or less (preferably 5 V or less), and the write voltage VD is about 6.5 V or more.
It may be controlled in the range of about 10.5V.

In the above driving method, the first reset voltage VR for aligning the liquid crystal 11 in the first alignment direction 11a and the liquid crystal 11 for the second alignment direction 11b are selected every selection period TS.
Since the second reset voltage −VR for orienting in the same direction is alternately applied at the same number of times (once in the above embodiment),
A direct current component equal to or more than the allowable value does not deviate to the liquid crystal 11 in a biased manner, and therefore a display burn-in phenomenon or deterioration of the liquid crystal does not occur.

In the above embodiment, the reset voltage VR
, -VR are applied in the order of the first reset voltage VR and the second reset voltage -VR. The reset voltage VR,
The application order of -VR may be reversed, and the reset voltages VR and -VR are almost the same for the liquid crystal 11 as the first and second reset voltages.
If the voltage is oriented in the orientation directions 11a and 11b, the voltage may not be completely oriented in the orientation directions 11a and 11b.

In the above embodiment, the first reset voltage VR and the second reset voltage -VR are applied once, but the number of times these reset voltages VR, -VR are applied may be arbitrary. , The first reset voltage VR and the second reset voltage −VR may be alternately applied at the same number of times.

Further, in the ferroelectric liquid crystal display device driven in the above embodiment, the transmission axis 14a of one polarizing plate 14 is DH.
Although the second alignment direction 11b of the F liquid crystal 11 is made substantially parallel to it, in the above driving method, the transmission axis 14a of one polarizing plate 14 is made substantially parallel to the first alignment direction 11a of the DHF liquid crystal 11. , The transmittance is highest when the liquid crystal 11 is aligned in the second alignment direction 11b (the display is brightest), and the transmittance is lowest when the liquid crystal 11 is aligned in the first alignment direction 11a ( It can also be applied to drive a ferroelectric liquid crystal display device in which the display becomes darkest.
The invention can be applied not only to the one using the TFT as the active element but also to the driving of the ferroelectric liquid crystal display element using the MIM as the active element.

[0066]

According to the driving method of the present invention, the selection period
At least one of the voltage for orienting the liquid crystal in the first orientation state and the voltage for orienting the liquid crystal in the second orientation state is applied.
Since the liquid crystal molecules are brought into one of the alignment states and the write voltage is applied thereafter, the active matrix type ferroelectric liquid crystal using the non-memory type ferroelectric liquid crystal (DHF liquid crystal) having a spiral pitch smaller than the substrate interval is used. It is possible to cause the dielectric liquid crystal display element to perform clear gradation display.

[Brief description of drawings]

FIG. 1 is a diagram showing waveforms of a gate signal and a data signal, and an average charge amount and transmittance due to spontaneous polarization of liquid crystal according to an embodiment of the present invention.

FIG. 2 is a voltage-transmittance characteristic diagram when a ferroelectric liquid crystal display element is driven by the driving method of the example.

FIG. 3 is a sectional view of a ferroelectric liquid crystal display element.

FIG. 4 is an equivalent circuit plan view of a substrate on which pixel electrodes and active elements are formed.

FIG. 5 is a diagram showing two alignment states of DHF liquid crystal and directions of transmission axes of a pair of polarizing plates.

FIG. 6 is a general voltage-transmittance characteristic diagram of a ferroelectric liquid crystal display device.

Figure 7 is a waveform chart of the gate signal and the data signal applied in driving dynamic tests inventors have conducted.

FIG. 8 is a diagram showing an average charge amount and transmittance due to spontaneous polarization of liquid crystal when a drive test is performed with a voltage value of a write pulse set to 0V.

FIG. 9 shows the voltage value of the write pulse at 3.3V and -3.3V.
The figure which shows the average electric charge amount and the transmittance | permeability by the spontaneous polarization of the liquid crystal at the time of performing a drive test.

[Explanation of reference numerals] 3 ... Pixel electrode 4 ... Active element (TFT) 7 ... Counter electrode 8, 9 ... Alignment film 11 ... DHF liquid crystal 11a ... First alignment direction 11b ... Second alignment direction 13, 14 ... Polarizing plate 13a, 14a ... Transmission axis P11 ... Compensation pulse P12, P13 ... Reset pulse VR, -VR ... Reset voltage P14 ... Write pulse VD ... Write voltage

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Claims (1)

[Claims] 1. A spiral pitch smaller than a substrate interval, and when a voltage equal to or higher than a threshold value is applied, it is brought into one of a first alignment state and a second alignment state depending on the polarity of the applied voltage. A method for driving an active matrix type ferroelectric liquid crystal display device using non-memory type ferroelectric liquid crystal to be aligned, comprising: a voltage for orienting the liquid crystal in a first alignment state and a second A method for driving a ferroelectric liquid crystal display device, characterized in that a voltage for orienting in an aligned state is applied alternately in the same order by the same number of times, and then a writing voltage is applied.