JPH08278482A - Method and device for driving image display device - Google Patents

Abstract

PURPOSE: To reduce the extent of a residual of a voltage applied to a row electrode and to reduce a ghost by lowering the voltage applied to the row electrodes before lowering the voltage applied to a column electrodes. CONSTITUTION: A column dot counter 61 counts a clock signal 141 with an input of a horizontal synchronizing signal 142 as a trigger. When the fact that the column dot counter 61 counts the clock signal by one row is detected, a decoder 62 outputs an LD signal 201 to a signal line, and outputs an LP signal 221 to the signal line. A column driver 80 applies the voltage answering to an L-th sub-group inputted until then to the column electrodes of a liquid crystal panel according to the LD signal 201. Further, a row driver 90 applies the voltage answering to a row selection pattern to respective row electrodes of the L-th subgroup according to the LP signal 221. Then, a voltage waveform applied to the row electrode is lowered a little early.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving method and a driving device suitable for driving an image display device such as a liquid crystal display device in which a plurality of row electrodes are collectively selected and driven.

[0002]

2. Description of the Related Art Since a liquid crystal display device is thin, light and compact, it has been widely used in OA equipment and the like in recent years. Liquid crystal display devices generally have a difficulty in high-speed display such as moving image display as compared with CRTs and the like. As a method for solving such a difficulty, a multiple line simultaneous selection method (MLS method) has been proposed in which a plurality of row electrodes are selected and driven at once. In the MLS method, in order to independently control the display pattern in the column direction (column display pattern), a constant voltage pulse train is applied to each row electrode selected simultaneously. Since a plurality of row electrodes are selected at the same time, voltage pulses are simultaneously applied to the plurality of row electrodes. At this time, in order to control the column display patterns simultaneously and independently, it is necessary to apply pulse voltages having different polarities to the row electrodes. Therefore, a pulse voltage having a polarity is applied to each row electrode several times, and an effective voltage corresponding to ON / OFF is applied to each pixel as a whole. The voltage pulse train applied to each row electrode is hereinafter also referred to as a selection pulse voltage group.

The selection pulse voltage group applied to each row electrode is a matrix of L rows and K columns, where L is the number of row electrodes selected at the same time (this matrix is hereinafter referred to as a selection matrix (A)).
Can be expressed as The selection pulse voltage group can be represented as a vector group orthogonal to each other. Therefore, a matrix including each vector as a column element is an orthogonal matrix. That is,
Each row vector in the matrix is orthogonal.

FIG. 14 is an explanatory diagram showing an example of a sequence of voltage waveforms applied to the selection matrix (A) and column electrodes. As a typical example of the selection matrix (A), there is a Hadamard matrix or a partial matrix in which a specific row is removed from the Hadamard matrix. Here, as the selection matrix (A), a 4 × 4 Hadamard matrix is exemplified. There is. In the selection matrix (A), each row corresponds to one of the four rows that are simultaneously selected. For example, the element in the first row of the selection matrix (A) is applied to the column electrode corresponding to L = 1, and 1 in the first row is applied.
The selection pulse is applied in the order of the elements in the second column and the elements in the second column. In the selection matrix (A), "1" means a positive pulse and "-1" means a negative pulse.

A voltage level corresponding to each column element of this matrix and a column display pattern is applied to the column electrode. That is, the sequence of voltages applied to the column electrodes is determined by the selection matrix (A) and the column display pattern. The sequence of voltages applied to the column electrodes is determined as follows. For example, it is assumed that the display data corresponding to the column electrode i and the column electrode j is as shown in FIG. The column display pattern is represented by a vector (d) as shown in FIG. Here, the element "-1" indicates ON display, and "1"
Indicates off display. When voltage pulses are sequentially applied to each row electrode in the order of columns in the selection matrix (A) (first column, second column, ...), the sequence of voltages applied to the column electrodes is as shown in FIG. It becomes like the vector (v) shown in (b). That is, the voltage waveform applied to the column electrodes is
This is as shown in FIG.

In the case of the MLS method, it is desirable that the applied voltage pulses are dispersed within one display cycle in order to suppress the frame response of the liquid crystal display element. For example, the first element of the vector (v) for the first row electrode group (hereinafter, referred to as a subgroup) that is simultaneously selected is applied to the column electrode, and then the second element is selected simultaneously. It is preferable that the first element of the vector (v) for the row electrode group of is applied to the column electrode and the same sequence be repeated thereafter. The sequence of voltages actually applied to the column electrodes is determined by how the applied voltage pulses are distributed within one display pulse and how the selection matrix (A) is chosen.

FIG. 15 is a block diagram showing an example of a driving device for realizing the MLS method. In the circuit shown in FIG. 15, the digitized serial data of R, G, B is converted into parallel data by the serial-parallel converter 10, and then the memory 20
Is written to. The data read from the memory 20 is format-converted by the format converter 30 and supplied to the column signal generator 40. The column signal generator 40 also uses the signal from the row selection pulse generator 70 to create a column signal applied to each column electrode. The column signal is supplied to the column driver 80. The column driver 80 creates a column voltage of a predetermined level from the column signal and applies it to the column electrode of the liquid crystal panel 1.

On the other hand, the signal from the row selection pulse generator 70 is also input to the row driver 90. Row driver 90
Generates a voltage pulse applied to each row electrode and applies it to each row electrode of the liquid crystal panel 1. The column driver 80
The timing of the row driver 90 is controlled by a control signal from the driver control circuit 60 via the signal lines 200 and 220. Further, the driver control circuit 60 is timing-controlled by a signal from the timing control circuit 50 via the signal line 140.

FIG. 16 is a timing chart showing the timing relationship between the column voltage and each control signal. 16, (a) is a column signal supplied to the column driver 80, (b) is a load (LD) signal given from the driver control circuit 60 to the column driver 80 via the signal line 200, and (c) is a column. A signal output from the driver 80, (d) is a row selection pattern provided from the row selection pulse generator 70 to the row driver 90, and (e) is provided from the driver control circuit 60 to the row driver 90 via the signal line 220. Latch pulse (LP) signal, (f) shows a signal output from the row driver 90.

FIG. 17 is a block diagram showing an example of the configuration of the driver control circuit 60. As shown in FIG. 17, the column dot counter 61 receives the clock signal 141 and the horizontal synchronizing signal 142 from the timing control circuit 50 and counts the clock signal 141.
When the decoder 62 detects that the count value of the column dot counter 61 has reached a predetermined number, it outputs the LD signal 201 and the LP signal 221. Although not shown in the figure, the count value of the column dot counter 61 is reset by the output of the decoder 62.

Next, the operation will be described with reference to FIGS. 15 and 16. The digitized R, G, B serial data is converted into parallel data by the serial-parallel converter 10 and then written in the memory 20. The data read from the memory 20 is vertically and horizontally converted by the format converter 30 and supplied to the column signal generator 40 as a column display pattern. The row selection pulse generator 70 outputs a row selection pattern. The column signal generator 40 performs a predetermined calculation using the column display pattern and the row selection pattern to generate a column signal. The generated column signal is sequentially output to the column driver 80 (see FIG. 16A).
The column driver 80 sequentially shifts the input column signal. The row driver 90 is a row selection pulse generator 7
Row selection patterns from 0 are sequentially input (FIG. 16D).
reference).

The timing control circuit 50 supplies the horizontal synchronizing signal 142 and the clock signal 141 to the driver control circuit 60. In the driver control circuit 60, the column dot counter 6
1 counts the clock signal 141 triggered by the input of the horizontal synchronization signal 142. Column dot counter 61
Detects that it has counted the clock signals of one row (for example, 640 pixels), the decoder 62 determines that the signal line 2
The LD signal 201 is output to 00 and the LP signal 221 is output to the signal line 220 (see FIGS. 16B and 16E). At this time, the column signal for one row has been input to the column driver 80. In the example illustrated in FIG. 16, the column signal (Sub (L) data) corresponding to the L-th subgroup is input to the column driver 80. Then, the column driver 80 responds to the LD signal 201 by
A voltage corresponding to the data of Sub (L) is applied to the column electrode. Further, the row driver 90 applies a voltage corresponding to the row selection pattern to each selected row electrode according to the LP signal 221.

FIG. 18 is a circuit diagram showing an equivalent circuit of the liquid crystal display panel 1. This equivalent circuit is a circuit when the number of row electrodes selected at the same time is 7 and the number of subgroups is M. As shown in the figure, the row electrodes R1 to Rm and the column electrode C1
A capacitance appears between .about.Cn. By the existence of capacity,
The voltage waveform actually applied to the row electrodes is distorted. Particularly, as the distance from the driving end of the row electrode increases, the influence of the resistance of the electrode increases, so that the degree of strain increases. Here, the number of row electrodes selected at the same time is 7, but of course,
The value is not limited to 7.

FIG. 19 is a timing chart showing the voltages actually applied to the row electrodes. FIG. 19A shows a voltage waveform at the column electrode Ci near the driving end of the row electrode.
(B) shows a voltage waveform at the column electrode Cj far from the driving end of the row electrode. In the figure, the horizontal axis represents time, and VSub (L-
1) / Ci indicates that it is the voltage for the (L-1) th subgroup on the column electrode Ci. The result of waveform distortion,
As shown in FIG. 19B, at the column electrode Cj, the fall of the voltage applied to the row electrode is delayed. Therefore, when a certain row electrode is being driven, a phenomenon in which an image appears in a row corresponding to the row electrode driven immediately before, that is, a so-called ghost may occur. In the case of line-sequential driving, a ghost appears on the immediately preceding line on the actual screen, so it is not so noticeable.
However, in the case of the MLS method, a ghost is generated in the row one subgroup before, so that it is more noticeable than in the case of line-sequential driving.

For example, as shown in FIG. 20, when the L-th subgroup is driven, the display appears in the (L-1) subgroup. In FIG. 20, in the column electrode Cj far from the driving end of the electrode, when the first row of the L-th subgroup is lit, the subgroup of (L-1) is separated from the first row by 7 rows. The first row is also shown to be dimly lit.

[0016]

In the conventional driving method based on the MLS method, as described above, since the ghost resulting from the distortion of the applied voltage waveform appears at a position apart from the lighting portion, display unevenness is easily noticeable. was there.

An object of the present invention is to provide a driving method and a driving device for an image display device which can solve such problems and suppress display unevenness.

[0018]

According to a first aspect of the present invention, there is provided a method of driving an image display device, wherein a plurality of row electrodes of an image display device having a plurality of row electrodes and a plurality of column electrodes are collectively selected. Then, a driving method of applying a voltage based on a signal obtained by time-sequentially developing a column vector of an orthogonal matrix to each selected column electrode, and applying a voltage applied to the column electrode to at least some of the pixels. The step of lowering the voltage applied to the row electrode is included before the lowering.

According to a second aspect of the present invention, there is provided a method of driving an image display device, wherein at least some of the pixels are supplied with a voltage applied to a row electrode before the voltage applied to a column electrode is raised. It further includes the step of starting up.

According to a third aspect of the present invention, there is provided a method of driving an image display device, wherein as the column electrode is separated from the driving end of the row electrode, the fall of the voltage applied to the column electrode and the voltage applied to the row electrode are reduced. This includes the step of increasing the interval with the falling edge.

According to a fourth aspect of the present invention, there is provided a drive device for an image display device, comprising a column driver for driving each column electrode in an image display device having a plurality of row electrodes and a plurality of column electrodes, and a plurality of row electrodes. A drive device including a row driver that collectively selects and applies a voltage based on a signal obtained by time-sequentially developing a column vector of an orthogonal matrix to each selected column electrode, wherein at least some pixels are , A driver control circuit for controlling the column driver and the row driver is provided so that the row driver lowers the voltage applied to the row electrode before the timing when the column driver lowers the voltage applied to the column electrode. is there.

According to a fifth aspect of the present invention, there is provided a drive device for an image display device, wherein the driver control circuit, at least for some pixels, has a low voltage before the column driver raises the voltage applied to the column electrodes. The column driver and the row driver are controlled so that the driver raises the voltage applied to the row electrode.

According to a sixth aspect of the present invention, there is provided a driving apparatus for an image display apparatus, wherein the driver control circuit causes the voltage applied to the column electrode by the column driver to fall as the column electrode moves away from the driving end of the row electrode. The column driver and the row driver are controlled so that the interval between the fall of the voltage applied to the row electrode by the row driver and the fall of the voltage is increased.

[0024]

In the step of lowering the voltage applied to the row electrode before lowering the voltage applied to the column electrode in the first aspect of the invention, the voltage applied to the row electrode is applied to the column electrode. Start switching earlier than the
Even if the fall of the voltage applied to the row electrode is distorted, the residual level of the voltage applied to the row electrode is reduced and the ghost is reduced.

In the step of raising the voltage applied to the row electrode before raising the voltage applied to the column electrode in the second aspect of the invention, the voltage applied to the row electrode is applied to the column electrode. The voltage starts to switch earlier than the effective voltage, and the effective voltage value applied to the row electrode reaches a desired value, which reduces ghost and prevents the contrast ratio from decreasing.

In the step of lowering the voltage applied to the row electrode before lowering the voltage applied to the column electrode according to the third aspect of the invention, a portion far from the driving end of the row electrode and having a large voltage waveform distortion. Only in this case, it becomes possible to control so that the voltage applied to the row electrode falls before the voltage applied to the column electrode falls.

According to another aspect of the invention, the driver control circuit controls so that the voltage applied to the row electrode starts to switch earlier than the voltage applied to the column electrode, and the voltage applied to the row electrode rises. Even if the fall is distorted, the degree of residual voltage applied to the row electrodes is reduced to reduce ghost.

According to a fifth aspect of the present invention, the driver control circuit controls the voltage applied to the row electrode to start switching earlier than the voltage applied to the column electrode, and the effective voltage applied to the row electrode. The value is controlled to a desired value to reduce ghost and prevent the contrast ratio from decreasing.

According to the sixth aspect of the present invention, in the driver control circuit, the row electrodes are applied to the row electrodes before the voltage applied to the column electrodes falls only at a place far from the driving end of the row electrodes and the voltage waveform distortion is large. It is possible to control the applied voltage so that it falls.

[0030]

Embodiments of the present invention will be described below. In each embodiment, the number of row electrodes selected at the same time is seven. Example 1. FIG. 1 is a block diagram showing an example of a driver control circuit in a drive device for an image display device according to a first embodiment of the present invention, together with a column driver 80 and a row driver 90. As shown in the figure, the column dot counter 61 inputs the clock signal 141 and the horizontal synchronizing signal 142 from the timing control circuit 50 and counts the clock signal 141. The decoder 62 detects that the count value of the column dot counter 61 has reached a predetermined number. LD signal 201 and LP signal 22
Outputs 1. Further, when the decoder 63 detects that the count value of the column dot counter 61 reaches a predetermined number, it outputs a DISP-OFF signal. DISP-O
The FF signal is a signal for forcibly invalidating the output of the row driver 90. That is, when the DISP-OFF signal is input to the row driver 90, all the outputs become insignificant. In FIG. 1, it is clearly shown that the DISP-OFF signal is low active. The components of the drive device other than the driver control circuit are
The configuration shown in FIG. 15 may be used.

Next, the operation will be described with reference to the timing charts of FIGS. 1 and 2. In FIG. 2, (a) is a column signal supplied to the column driver 80, (b) is an LD signal given from the driver control circuit to the column driver 80 via the signal line 200, and (c) is an output from the column driver 80. Signal, (d) is a row selection pattern given from the row selection pulse generator 70 to the row driver 90, and (e) is LP given from the driver control circuit to the row driver 90 via the signal line 220.
Signal, (f) is a signal output from the row driver 90,
(G) is the DI output from the driver control circuit
An SP-OFF signal is shown.

The serial data includes serial / parallel converter 10, memory 20, format converter 30, column signal generator 40, column driver 80, row selection pulse generator 7.
0 and the operation of the timing control circuit 50 are shown in FIG.
The operation is the same as that of the apparatus shown in FIG.

In the driver control circuit, the column dot counter 61 counts the clock signal 141 triggered by the input of the horizontal synchronizing signal 142. When the column dot counter 61 detects that the clock signal 141 for one row is counted, the decoder 62 outputs the LD signal 201 to the signal line 200 and outputs the LP signal to the signal line 220.
The signal 221 is output (see timing t _{2 in} FIGS. 2B and 2E). The column driver 80 outputs the LD signal 201
Accordingly, the voltage corresponding to the L-th subgroup (Sub (L)) that has been input until then is applied to the column electrode of the liquid crystal panel 1. Further, the row driver 90 applies a voltage corresponding to the row selection pattern to each row electrode of the L-th subgroup in response to the LP signal 221.

In the driver control circuit, when the decoder 63 detects that the column dot counter 61 has counted a predetermined number of clock signals, the DISP-
An OFF signal is output (see timing t _{1 in} FIG. 2G). Here, the predetermined number is a value smaller than the number of clocks for one row by the number of clocks corresponding to ΔT shown in FIG. When the DISP-OFF signal is input, the row driver 90 invalidates the output given to each row electrode of the liquid crystal display panel 1. Therefore, as shown in FIG. 3, the voltage waveform applied to the row electrode falls early. Note that FIG.
19A shows a voltage waveform at the column electrode Ci close to the driving end of the row electrode similarly to FIG. 19A, and FIG.
Similar to FIG. 19B, the column electrode C far from the driving end of the row electrode
The voltage waveform at j is shown.

Before the LD signal 201 and the LP signal 221 are output, that is, before the timing t ₂ , the column driver 80 has the (L-1) th subgroup (Su).
A voltage corresponding to b (L-1)) is applied to the column electrodes of the liquid crystal panel 1. Further, before the timing t ₁ , the row driver 90 applies the voltage according to the row selection pattern to the (L−1) th subgroup. The non-selection voltage is applied between the timing t ₁ and the timing t ₂ .

According to the conventional driving method, as shown in FIG. 19B, the fall of the applied voltage waveform is delayed at the column electrode Cj far from the driving end of the row electrode, and the delay causes the display unevenness. Was becoming. However, according to this driving method, the applied voltage waveform falls early as shown in FIG. 3B, and thus display unevenness is reduced as shown in FIG.

Example 2. FIG. 5 is a block diagram showing an example of a driver control circuit in a driving device for an image display device according to the second embodiment of the present invention. As shown in the figure, the column dot counter 61 receives the clock signal 141 and the horizontal synchronizing signal 142 from the timing control circuit 50 and counts the clock signal 141. When the decoder 64 detects that the count value of the column dot counter 61 reaches a predetermined number, the LD signal 201
When it is detected that the count value of the column dot counter 61 reaches another predetermined number, the LP signal 223 is output. In the first embodiment, the decoder 62 outputs the LD signal 201 and the LP signal 221 at the same timing. However, in this case, the timing at which the decoder 64 outputs the LD signal 201 is different from the timing at which the LP signal 223 is output. The components of the driving device other than the driver control circuit may have the configuration shown in FIG.

Next, the operation will be described with reference to the timing charts of FIGS. 6, (a) is a column signal supplied to the column driver 80, (b) is an LD signal given from the driver control circuit to the column driver 80 via the signal line 200, and (c) is an output from the column driver 80. Signal, (d) is a row selection pattern given from the row selection pulse generator 70 to the row driver 90, and (e) is LP given from the driver control circuit to the row driver 90 via the signal line 220.
Signals (f) indicate signals output from the row driver 90.

The serial data includes serial / parallel converter 10, memory 20, format converter 30, column signal generator 40, column driver 80, row selection pulse generator 7.
0 and the operation of the timing control circuit 50 are shown in FIG.
The operation is the same as that of the apparatus shown in FIG.

In the driver control circuit, the column dot counter 61 counts the clock signal 141 triggered by the input of the horizontal synchronizing signal 142. When the column dot counter 61 detects that the clock signal 141 for one row is counted, the decoder 64 outputs the LD signal 201 to the signal line 200 (see timing t _{2 in} FIG. 6B). The column driver 80 outputs the LD signal 2
In response to 01, the voltage corresponding to the L-th subgroup (Sub (L)) that has been input until then is applied to the column electrode of the liquid crystal panel 1.

The decoder 64 uses the column dot counter 6
When detecting that 1 has counted a predetermined number of clock signals, the LP signal 223 is output. Here, the predetermined number is a value smaller than the number of clocks for one row by the number of clocks corresponding to ΔT shown in FIG. Row driver 90
Applies a voltage corresponding to the row selection pattern to each row electrode of the L-th subgroup according to the LP signal 223. Therefore, as shown in FIG. 7, the timing at which the voltage is applied to each row electrode of the L-th subgroup is earlier by ΔT than the timing at which the corresponding column voltage is applied to each column electrode. This is
The same applies to the other subgroups. Note that (L +
1) Since the timing at which the voltage starts being applied to each row electrode of the 1st subgroup is advanced, the timing at which the voltage is applied to each row electrode of the Lth subgroup is advanced by ΔT.

Therefore, as shown in FIG. 7, the timing at which the voltage corresponding to each row electrode is applied is deviated from the timing at which the voltage is applied to each column electrode by ΔT. Note that FIG. 7A shows a voltage waveform at the column electrode Ci near the driving end of the row electrode, as in FIG.
19B shows a voltage waveform at the column electrode Cj far from the driving end of the row electrode, as in FIG. 19B. As a result of being driven in this way, the waveform of the applied voltage applied to the row electrodes falls early as shown in FIG. 7B, and thus display unevenness is reduced as shown in FIG. In this case, L
When the first of the th subgroup is lit,
There is a possibility that the first sub-group of the (L + 1) subgroup, which is located 7 lines away from the light source, may be lightly turned on, but the degree of lighting is small and can be ignored. Further, in the first embodiment, since the width of the voltage pulse applied to the row electrode becomes small, the voltage actually applied to the row electrode may deviate from the voltage value at which the contrast ratio becomes the highest. In this case, the width of the voltage pulse applied to the row electrode is not reduced, and the maximum contrast ratio is obtained.

Example 3. FIG. 9 is a block diagram showing an example of a driving device for an image display device according to the third embodiment of the present invention. In the figure, in this case, it is clearly shown that the column driver is composed of a plurality of column drivers 81 and 82. Therefore, the driver control circuit 60A supplies separate LD signals to the respective column drivers 81 and 82 via the signal lines 120A and 120B. The components of the drive device other than the driver control circuit 60A and the column drivers 81 and 82 may have the configuration shown in FIG.

FIG. 10 shows a driver control circuit 60A.
It is a block diagram showing an example of 1 composition. As shown in the figure,
The column dot counter 61 receives the clock signal 141 and the horizontal synchronizing signal 14 from the timing control circuit 50.
Input 2 and count the clock signal. Decoder 6
5 outputs the LD signal 121 and the LP signal 131 when detecting that the count value of the column dot counter 61 reaches a predetermined number, and outputs the LD when detecting that the count value of the column dot counter 61 reaches another predetermined number. Traffic light 12
2 is output.

Next, the operation will be described with reference to the timing charts of FIGS. In FIG.
(A) is a column signal supplied to the column driver 80,
(B1) is an LD given to the column driver 81 from the driver control circuit 60A via the signal line 120A.
Signal, (b2) is an LD signal given from the driver control circuit 60A to the column driver 82 via the signal line 120B, (c1) is a signal output from the column driver 81, and (c2) is output from the column driver 82. Signal, (d) is a row selection pattern provided from the row selection pulse generator 70 to the row driver 90, (e) is an LP signal provided from the driver control circuit 60A to the row driver 90 via the signal line 130, (f) Indicates a signal output from the row driver 90.

For serial data, the operations of the serial-parallel converter 10, the memory 20, the format converter 30, the column signal generator 40, the row selection pulse generator 70 and the timing control circuit 50 are the same as those in the apparatus shown in FIG. .

In the driver control 60A circuit, the column dot counter 61 has a horizontal synchronizing signal 142.
The clock signal 141 is counted by the input of. When the column dot counter 61 detects that the clock signal 141 for one row has been counted, the decoder 65
Outputs the LD signal 121 to the signal line 120A (see FIG. 1).
1 (b1) timing t1). Also, the decoder 6
5 outputs the LP signal 131 (see timing t _{1 in} FIG. 11E). The column driver 81 outputs the LD signal 1
In accordance with No. 21, a voltage corresponding to the L-th subgroup (Sub (L)) that has been input so far is applied to the column electrode of the liquid crystal panel 1. Further, the row driver 90 is L
According to the P signal 131, a voltage corresponding to the row selection pattern is applied to each row electrode of the L-th subgroup.

The decoder 65 uses the column dot counter 6
When detecting that 1 has counted a predetermined number of clock signals, the LP signal 122 is output (see timing t _{2 in} FIG. 11B2). Here, the predetermined number is a value larger than the number of clocks for one row by the number of clocks corresponding to ΔT shown in FIG. In response to the LD signal 122, the column driver 82 applies a voltage corresponding to the L-th subgroup (Sub (L)) that has been input until then to the column electrode of the liquid crystal panel 1.

By using such a driving method, as shown in FIG. 12A, the timing at which a voltage is applied to each column electrode close to the drive end of the row electrode which the column driver 81 is responsible for and the voltage applied to each row electrode. Coincides with the timing at which is applied. In addition, as shown in FIG.
When each column electrode handled by the column driver 82 is far from the drive end of the row electrode, the rising and falling waveforms of the row voltage are blunted, so that the rising and falling of the column voltage are delayed accordingly. Therefore, at a position near the drive end of the row electrode that is not significantly affected by the capacitance appearing between the electrodes, the timing when the voltage is applied to each column electrode and the timing when the voltage is applied to each row electrode match, The relationship between the timing of applying the voltage to each column electrode and the timing of applying the voltage to each row electrode is the same as that in the second embodiment at a position far from the driving end of the electrode. That is, the waveform of the applied voltage applied to the row electrode falls earlier than the corresponding fall of the column voltage, so that the display unevenness is reduced as shown in FIG. Also in this case, when the first row of the L-th subgroup is lit, the first row of the (L + 1) subgroup 7 rows away from the first row may be dimly lit. However, the degree of lighting is small and can be ignored.

[0050]

As described above, according to the first aspect of the invention, the driving method of the image display device is such that the voltage applied to the row electrodes is changed before the voltage applied to the column electrodes is lowered. Since the method includes the step of falling, it is possible to provide the image display device in which the voltage applied to the row electrode starts to switch earlier than the voltage applied to the column electrode. That is,
Even if the voltage applied to the row electrode falls off, the residual level of the voltage applied to the row electrode is reduced and the display unevenness is reduced.

According to a second aspect of the present invention, there is provided a method of driving an image display device, including a step of raising a voltage applied to a row electrode before raising a voltage applied to a column electrode. Therefore, it is possible to provide an image display device in which the voltage applied to the row electrodes starts to switch earlier than the voltage applied to the column electrodes while the effective voltage value applied to the row electrodes is kept at a desired value. That is, even if the fall of the voltage applied to the row electrode becomes gentle, the display unevenness is reduced and the contrast ratio is prevented from being lowered.

According to the third aspect of the present invention, the driving method of the image display device is such that the fall of the voltage applied to the column electrode and the voltage applied to the row electrode as the column electrode moves away from the driving end of the row electrode. Since the method includes the step of increasing the interval with the trailing edge of the row electrode, the voltage applied to the row electrode before the voltage applied to the column electrode falls only at the location far from the driving end of the row electrode. It becomes possible to control to fall. That is, the control for changing the timing of the voltage waveform is not performed for the portion where the distortion of the voltage waveform is small, and the display unevenness can be reduced for the portion where the distortion of the voltage waveform is large. By this control, there is an effect that display unevenness can be appropriately reduced according to the place on the screen.

According to the fourth aspect of the present invention, there is provided a driver control circuit for controlling the driving device of the image display device so that the voltage applied to the row electrodes starts to switch earlier than the voltage applied to the column electrodes. Since the configuration is provided, it is possible to provide the image display device in which the voltage applied to the row electrode starts to switch earlier than the voltage applied to the column electrode. That is, even if the voltage applied to the row electrode falls off, the residual level of the voltage applied to the row electrode is reduced and the display unevenness is reduced.

According to the fifth aspect of the present invention, the driving device of the image display device is controlled so that the voltage applied to the row electrodes starts to switch earlier than the voltage applied to the column electrodes, and the row electrodes are controlled. Since the driver control circuit that controls the effective voltage value applied to the row electrode to the desired value is provided, the effective voltage value applied to the row electrode is applied to the row electrode with the desired value. It is possible to provide an image display device in which the applied voltage starts to switch earlier than the voltage applied to the column electrodes. That is, even if the fall of the voltage applied to the row electrode becomes gentle, the display unevenness is reduced and the contrast ratio is prevented from being lowered.

According to the sixth aspect of the present invention, the voltage applied to the row electrode falls only before the voltage applied to the column electrode falls only at a position far from the driving end of the row electrode. Since the driver control circuit for controlling the row electrodes is provided, the voltage applied to the row electrodes falls only before the voltage applied to the column electrodes falls only at the location far from the driving end of the row electrodes. It becomes possible to control. That is, the control for changing the timing of the voltage waveform is not performed for the portion where the distortion of the voltage waveform is small, and the display unevenness can be reduced for the portion where the distortion of the voltage waveform is large. By this control, there is an effect that display unevenness can be appropriately reduced according to the place on the screen.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a driver control circuit in a drive device for an image display device according to a first embodiment of the present invention together with a column driver and a row driver.

FIG. 2 is a timing chart showing a timing relationship between a column voltage and a row voltage and respective control signals in the first embodiment.

FIG. 3 is a timing chart showing switching timings of a column voltage and a row voltage in the first embodiment.

FIG. 4 is an explanatory diagram showing a display result in the first embodiment.

FIG. 5 is a block diagram showing an example of a driver control circuit in a driving device of an image display device according to a second embodiment of the present invention.

FIG. 6 is a timing chart showing a timing relationship between a column voltage and a row voltage and respective control signals in the second embodiment.

FIG. 7 is a timing chart showing switching timings of a column voltage and a row voltage in the second embodiment.

FIG. 8 is an explanatory diagram showing a display result in the second embodiment.

FIG. 9 is a block diagram showing a driving device of an image display device according to a third embodiment of the present invention.

FIG. 10 is a block diagram showing an example of a driver control circuit in a driving device for an image display device according to a third embodiment.

FIG. 11 is a timing chart showing a timing relationship between a column voltage and a row voltage and respective control signals in the third embodiment.

FIG. 12 is a timing chart showing the switching timing of the column voltage in the third embodiment.

FIG. 13 is an explanatory diagram showing a display result in the third embodiment.

FIG. 14 is an explanatory diagram for explaining a driving method by the MLS method.

FIG. 15 is a block diagram showing a drive device of a conventional image display device.

FIG. 16 is a timing chart showing a timing relationship between a column voltage and a row voltage and respective control signals in a conventional driving device.

FIG. 17 is a block diagram showing an example of a driver control circuit in a drive device of a conventional image display device.

FIG. 18 is a circuit diagram showing an equivalent circuit of a liquid crystal display panel.

FIG. 19 is a timing chart showing switching timings of a column voltage and a row voltage in a conventional image display device driving device.

FIG. 20 is an explanatory diagram showing a display result in a driving device of a conventional image display device.

[Explanation of symbols]

 60A driver control circuit 61 column dot counter 62, 63, 64, 65 decoder 80 column driver 90 row driver

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Takeshi Kuwata 1150 Hazawa-machi, Kanagawa-ku, Yokohama, Kanagawa Prefecture Asahi Glass Co., Ltd. Central Research Laboratory

Claims (6)

[Claims] 1. A driving method for an image display device, comprising collectively selecting a plurality of row electrodes of an image display device having a plurality of row electrodes and a plurality of column electrodes and applying a predetermined voltage to each of the selected column electrodes. In the method, a driving method for an image display device is characterized in that, for at least some of the pixels, the voltage applied to the row electrode is lowered before the voltage applied to the column electrode is lowered. 2. The driving method for an image display device according to claim 1, wherein, for at least some of the pixels, the voltage applied to the row electrode is raised before the voltage applied to the column electrode is raised. 3. The distance between the fall of the voltage applied to the column electrode and the fall of the voltage applied to the row electrode is increased as the column electrode is separated from the driving end of the row electrode. 2. The method for driving the image display device according to 2. 4. A column driver for driving each column electrode in an image display device having a plurality of row electrodes and a plurality of column electrodes, and a plurality of row electrodes are collectively selected and a predetermined column electrode is selected. In a driving device of an image display device including a row driver for applying a voltage, at least a part of the pixels is operated by the row driver before the timing of lowering the voltage applied by the column driver to the column electrode. A driving device for an image display device, comprising a driver control circuit for controlling the column driver and the row driver so as to lower the voltage applied to the electrodes. 5. The driver control circuit, for at least some of the pixels, raises the voltage applied to the row electrodes by the row driver before raising the voltage applied to the column electrodes by the column driver. The driving device for an image display device according to claim 4, wherein the column driver and the row driver are controlled. 6. The driver control circuit includes an interval between the fall of the voltage applied to the column electrode by the column driver and the fall of the voltage applied to the row electrode by the row driver as the column electrode moves away from the driving end of the row electrode. 6. The drive device for an image display device according to claim 4, wherein the column driver and the row driver are controlled so as to increase.