JPH06189232A - Liquid crystal driving method and liquid crystal display device - Google Patents

Abstract

PURPOSE:To provide a liquid crystal panel driving device which is capable of improving the response speed of the gradation change of a liquid crystal panel which performs a cumulative response. CONSTITUTION:In a liquid crystal panel drive device displaying an image, using a liquid crystal panel which performs a cumulative response, an image memory 11 storing the digital image data for which an A/D conversion is performed by an A/D conversion circuit 4 corresponding to one from is provided and a comparison circuit 12 performing a level comparison between digital image data to be outputted from the A/D conversion circuit 4 and image data to be read one-frame behind from the image memory 11 and outputting a gradation change signal is provided. This comparison circuit 12 selects normal liquid crystal driving voltage and performs the display and drive of the electrode of a liquid crystal. panel 8 when it judges that the level of the both comparison data is the same, and selects the liquid crystal drive voltage which is higher than the normal liquid crystal driving voltage and performs a display and drive of the electrode of the liquid crystal panel 8 when the level of the both comparison data is not the same.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal panel driving device for driving a liquid crystal panel used in, for example, a liquid crystal television.

[0002]

2. Description of the Related Art A conventional liquid crystal television is generally constructed as shown in FIG. In FIG. 1, reference numeral 1 is a television antenna, and television broadcast radio waves received by the antenna 1 are input to a tuner 2. The tuner 2 selects a radio wave of a designated channel from received radio waves, converts it into an intermediate frequency signal, and outputs it to the television linear circuit 3. The television linear circuit 3 extracts a video signal, a vertical synchronizing signal, and a horizontal synchronizing signal from the intermediate frequency signal from the tuner 2, and outputs the video signal to the A / D conversion circuit 4 and the synchronizing signal to the synchronization control circuit 5, respectively. . This synchronization control circuit 5
Generates various timing signals from the vertical synchronizing signal and the horizontal synchronizing signal, and outputs them to the A / D conversion circuit 4, the segment electrode driving circuit 6, and the common electrode driving circuit 7.

The A / D conversion circuit 4 includes a synchronization control circuit 5
The video signal is converted into several bits of digital data in synchronization with the sampling clock from and output to the segment electrode drive circuit 6. This segment electrode drive circuit 6 is
A gradation signal is created in accordance with the data from the A / D conversion circuit 4, and liquid crystal drive voltages V1 and V3 are further selected based on this gradation signal to create segment electrode drive signals, and the matrix type liquid crystal panel 8 is formed. The segment electrodes of are driven for display. In addition, the common electrode drive circuit 7 follows the liquid crystal drive voltage V0 according to the timing signal from the synchronization control circuit 5.
, V2, V4 are selected to generate a common electrode drive signal, and the common electrodes of the liquid crystal panel 8 are sequentially and selectively driven. The liquid crystal drive voltages V0 and V4 are selection voltages and V2 is a non-selection voltage.

[0004]

The liquid crystal panel 8 is driven based on the video signal received as described above. However, since the liquid crystal panel 8 operates by the cumulative response effect as shown in FIG. It has a slow response speed.

FIG. 6 shows the relationship between the liquid crystal drive voltage composite waveform and the light transmittance of the liquid crystal panel 8 when the gradation is "7" and "0". On the other hand, in the above-described conventional liquid crystal panel driving method, as shown in FIG. 6, the liquid crystal panel 8 is driven by simply creating the gradation signals corresponding to the video signals, and thus the liquid crystal panel 8 is driven. There was a problem that the response characteristics could not be improved and it was not possible to deal with fast moving images. The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a liquid crystal panel drive device capable of improving the response speed of gradation change of a liquid crystal panel.

[0006]

SUMMARY OF THE INVENTION The present invention provides a liquid crystal panel drive device for displaying an image using a liquid crystal panel which responds cumulatively, and an image memory for storing one frame of digital image data is provided. And a comparison circuit that outputs a gradation change signal by comparing the levels of the image data read from the image memory with a delay of one frame, and the comparison circuit determines that the levels of both comparison data are the same. , The normal liquid crystal drive voltage is selected to drive the electrodes of the liquid crystal panel for display, and when it is determined that the levels of the comparison data are not the same, the liquid crystal drive voltage higher than the normal liquid crystal drive voltage is selected. Thus, the electrodes of the liquid crystal panel are driven for display.

Further, according to the present invention, the gradation change signal is output from the comparison circuit, and when the image data of this time and the image data of one frame before are the same, the image data of this time is output as it is, and the image of this time is output. When the data is larger than the image data one frame before, the maximum value is output as the image data, and when the image data this time is smaller than the image data one frame before, the minimum value is output as the image data and the liquid crystal panel is displayed. The display is driven.

[0008]

With the above structure, the liquid crystal panel is driven at a high voltage when the image data changes, and thereby the response speed of the liquid crystal that responds cumulatively can be increased.

Further, when the image data changes, the liquid crystal panel is driven with the maximum gradation value or the minimum gradation value, so that the response speed of the liquid crystal panel can be further increased, and an image that changes abruptly can be obtained. It is possible to quickly follow up with it.

The term "frame" as used in the specification of the present application means that all picture elements that form one screen are scanned. For example, one picture element that forms one screen for each field of a TV signal. In a display device that scans and displays all in one way, one field of a TV signal and one frame referred to in the present application are considered to be equal to each other, and the "frame" generally used in a TV signal does not necessarily match. .

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows an example in which the present invention is applied to a liquid crystal television. The same parts as those in FIG. 5 are designated by the same reference numerals and detailed description thereof will be omitted.

In the present invention, as shown in FIG. 1, an image memory 11 and a comparison circuit 12 are provided on the output side of the A / D conversion circuit 4. The image memory 11 is a dual port memory capable of storing image data for one frame, operates according to a memory address and a read / write command given from the synchronization control circuit 5, and is sent from the A / D conversion circuit 4, for example, 3 The bit image data is sequentially stored, and after one frame, is sequentially output to the input terminal B of the comparison circuit 12. Also,
The input terminal A of the comparison circuit 12 has an A / D conversion circuit 4
The image data output from is input. The comparison circuit 12 includes an A / D conversion circuit 4 provided to input terminals A and B.
Of the image data from the image memory 11 and the image data read from the image memory 11 by one frame are compared in level, and the image data D1 to D3 are output from the output terminals P and Q according to the following rules.
And a gradation change signal E are output. A> B → P = 7, Q = 1 A = B → P = A, Q = 0 A <B → P = 0, Q = 1

The image data D1 to D3 output from the output terminal P of the comparison circuit 12 and the gradation change signal E output from the output terminal Q are sent to the segment electrode drive circuit 6 '. This segment electrode drive circuit 6'is
It is configured as shown in FIG.

In FIG. 2, reference numeral 21 denotes a data latch clock generation circuit, which is a data latch start signal STI synchronized with the horizontal synchronizing signal from the synchronization control circuit 5 and a clock pulse / φ.
1 (φ1 inverted signal) and / φ2 (φ2 inverted signal) are input. The data latch clock generation circuit 21
Data latch start signal STI is clock pulse / φ1,
It is read by / φ2 and sequentially shifted, and a data latch clock is generated at each shift.

The data latch clock generation circuit 21 outputs m data latch clocks corresponding to the number of segment electrodes of one horizontal line of the liquid crystal panel 8 in one horizontal period and sends them to the data latch circuits 22 of m stages. To be The data latch circuit 22 has a significantly 4-bit configuration, and the 3-bit image data D1 ...
D3 and the 1-bit gradation change signal E are latched in synchronization with the data latch clock.

The data latched by the data latch circuit 22 is read by a timing signal / φn (inverted signal of φn) given every horizontal period and sent to the gradation signal generating circuit 23. This gradation signal generation circuit 2
3 is a timing signal / φn, a gradation signal generating clock / φc (inversion signal of φc), a frame signal / φF (φF
3 bit image data D1 to D3 from the data latch circuit 22 is converted into a gradation signal having a pulse width, and is output to the analog multiplexer 24 together with the gradation change signal E. Further, the analog multiplexer 24 has liquid crystal driving voltages V1, V1 ', V2, V3, V.
3'is provided via the blanking control circuit 25.

Liquid crystal drive voltages V1, V1 ', V2, V3,
V3 'is V1 at a constant level interval centered on V2
(High level side) and V3 (Low level side) are set, and V1 'is set to a level higher than V1 and V3' is set to a level lower than V3. The blanking control circuit 25 is controlled in operation by a blanking control signal EC, and outputs the liquid crystal drive voltages V1, V1 ', V3, V3' as they are to the analog multiplexer 24 during the vertical blanking period except during the vertical blanking period. Liquid crystal drive voltages V1, V1 ', V3, V3' are all V2
The level is output to the analog multiplexer 24.
The analog multiplexer 24 selects one of the liquid crystal drive voltages V1, V1 ', V3, and V3' in accordance with the grayscale signal and the grayscale change signal from the grayscale signal generation circuit 23 to drive the segment electrode drive signal. Output to the liquid crystal panel 8 as Y1 to Ym.

FIG. 3 shows the analog multiplexer 24.
3 shows details of a circuit portion for generating a segment signal of one electrode in FIG. Liquid crystal drive voltages V1, V1 ', V3, V applied through the blanking control circuit 25
3'is input to the analog switches 31 to 34. The voltage selected by the analog switches 31 and 32 is sent to the output terminal 37 via the analog switch 35, and the voltage selected by the analog switches 33 and 34 is sent to the output terminal 37 via the analog switch 36.

The gradation change signal sent from the gradation signal generating circuit 23 is input to the control terminals of the analog switches 31 and 34 and also to the control terminals of the analog switches 32 and 33 via the inverter 38. To be done. Further, the grayscale signal sent from the grayscale signal generation circuit 23 is input to the control terminal of the analog switch 36 and also to the control terminal of the analog switch 35 via the inverter 39.

In the analog multiplexer 24 configured as described above, when the gradation change signal is "0", the analog switches 31 and 34 are turned off and the inverter 3
The output of 8 becomes "1" and the analog switches 32, 33
Is turned on, whereby the liquid crystal drive voltages V1 and V3 are selected and input to the analog switches 35 and 36. Since the analog switches 35 and 36 are ON / OFF controlled by a gradation signal given from the gradation signal generating circuit 23, the liquid crystal drive voltage V1 or V3 is selected according to the gradation signal and the segment is output from the output terminal 37. Electrode drive signal Y
Is sent to the liquid crystal panel 8.

When the gradation change signal is "1", the analog switches 31 and 34 are turned on and the output of the inverter 38 becomes "0".
33 is turned off, which causes liquid crystal drive voltages V1 'and V3'.
Is selected and input to the analog switches 35 and 36. Therefore, the liquid crystal drive voltage V1 'or V3' is selected according to the gradation signal and is sent from the output terminal 37 to the liquid crystal panel 8 as the segment electrode drive signal Y. In the vertical blanking period, the liquid crystal drive voltage applied from the blanking control circuit 25 is all at the V2 level, so the V2 voltage is used as the segment electrode drive signal Y regardless of the gradation change signal and the gradation signal. Sent to 8.

Next, the operation of the above embodiment will be described with reference to the timing chart of FIG. The 3-bit image data output from the A / D conversion circuit 4 is input to the input terminal A of the comparison circuit 12 and the image memory 11. The image memory 11 sequentially stores the image data sent from the A / D conversion circuit 4 under the control of the synchronization control circuit 5, and outputs it to the input terminal B of the comparison circuit 12 one frame later.

The comparison circuit 12 compares the image data output from the A / D conversion circuit 4 with the image data read from the image memory 11 with a delay of one frame, and compares the image data of one frame before with the current image. When the level of the data is higher, the maximum value "7", that is, "111" is output as the image data D1 to D3, and "1" is output as the gradation change signal.

If the level of the image data of one frame before and the image data of this time are the same, the comparison circuit 12 sets A
The image data sent from the / D conversion circuit 4 is output as it is as image data D1 to D3, and "0" is output as a gradation change signal. Further, the comparison circuit 12 outputs the minimum value "0", that is, "000" as the image data D1 to D3 when the level of the image data of this time is lower than that of the image data of one frame before, and also the gradation. "1" is output as a change signal.

The image data D1 to D3 and the gradation change signal E output from the comparison circuit 12 are sent to the segment electrode drive circuit 6 '. The segment electrode drive circuit 6'uses the image data D1 to D3 from the comparison circuit 12.
And segment electrode drive signals Y1 to Ym are generated based on the gradation change signal E to drive the segment electrodes of the liquid crystal panel 8.

FIG. 4 shows gradations of the relationship between the common electrode drive signal for the liquid crystal panel 8, the segment electrode drive signal, the composite waveform of the common electrode drive signal and the segment electrode drive signal, and the light transmittance of the liquid crystal with respect to this composite waveform. Is "0"
The figure shows a case where the change is made from "7" to "4".

Then, as shown in FIG. 4, the A / D
If the gradation of the image data output from the conversion circuit 4 changes from "0" to "7", the maximum value "7" is output as the data D1 to D3 from the comparison circuit 12 and the gradation change signal is output. "1" is output as E. This gradation change signal E is used together with the gradation signal in the segment electrode drive circuit 6 '.
After being sent to the data latch circuit 22, it is sent to the analog multiplexer 24 via the data latch circuit 22 and the gradation signal generating circuit 23.

The analog multiplexer 24 shown in detail in FIG. 3, when "1" is given as the gradation change signal E,
As described above, the analog switches 31 and 34 are turned on, the analog switches 32 and 33 are turned off, and the analog switches 35 and 36 are alternately turned on / off according to the gradation signal.
Since it is turned off, the liquid crystal drive voltage V1 ',
V3 'is selected and sent to the liquid crystal panel 8 as a segment electrode drive signal Y.

That is, in the first frame when the gradation of the image data changes from "0" to "7", the liquid crystal drive voltages V1 'and V3' are selected according to the gradation signal, and the segment signal Y is As shown by the broken line A1 in FIG. 4 (b), the phase is opposite to that of the common signal and has a larger amplitude than in the normal case. As a result, the composite waveform of the drive signal applied between the common and segment electrodes has an amplitude value "V0 + V1" larger than the normal levels "V0 + V1" and "V4 + V3", as indicated by the diagonal line A2 in FIG. "", "V4 + V3 '". In this way, the amplitude of the segment electrode drive signal is large, that is, the voltage is high, so that the liquid crystal panel 8
The light transmittance of the solid line B is as shown by the broken line A3 in FIG.
Rise is faster than in the conventional case shown in 1.

When the gradation "7" continues after the next frame, the comparison circuit 12 outputs the input terminal A.
The data given to the above are directly output as the image data D1 to D3, and "0" is output as the gradation change signal E. When the gradation change signal E is "0", the analog multiplexer 24 shown in FIG.
2, 33 are turned on, the liquid crystal drive voltages V1 and V3 are alternately selected according to the gradation signal, and the segment electrode drive signal Y
Is output to the liquid crystal panel 8.

When the same gradation continues as described above, the normal liquid crystal drive voltages V1 and V3 are selected in the second and subsequent frames. Further, as the same gradation level continues, the light transmittance of the liquid crystal panel 8 gradually increases due to the cumulative response effect as shown by the broken line A3 in FIG. 4D, and is constant at the level corresponding to the gradation "7". Becomes

Then, if the image data is thereafter lowered from the gradation "7" to the gradation "4" as shown in FIG. 4, the comparison circuit 12 sets the minimum value "0" as the image data D1 to D3. Output as well as "1" as gradation change signal E
Is output. When "1" is given as the gradation change signal E, the analog multiplexer 24 alternately selects the liquid crystal drive voltages V1 'and V3' according to the gradation signal as described above, and the liquid crystal panel as the segment electrode drive signal. Output to 8. In this case, since the gradation signal signal is "0", the segment signal Y has the same phase as the common electrode drive signal waveform as shown by the broken line A4 in FIG. 4 (b).

Therefore, the composite voltage waveform of the drive signal applied between the common and segment electrodes is a value "V0 + V1 '" obtained by cutting the portion indicated by the diagonal line A5 from the normal drive signal waveform as shown in FIG. 4 (c). , "V4 + V3 '".
That is, when the gradation changes to the lower side, the liquid crystal drive voltage becomes lower than the normal value in the first frame, and the light transmittance of the liquid crystal panel 8 is as shown by the broken line A6 in FIG. 4 (c). The rising speed is faster than in the conventional case shown by the solid line B2.

When the gradation "4" continues after the next frame, the comparison circuit 12 inputs the input terminal A
The data given to the above are directly output as the image data D1 to D3, and "0" is output as the gradation change signal E. When the gradation change signal E is "0", the analog multiplexer 24 alternately selects the liquid crystal drive voltages V1 and V3 according to the gradation signal, and outputs the segment electrode drive signal Y to the liquid crystal panel 8. When the same gradation continues in this way, the normal liquid crystal drive voltages V1 and V3 are selected in the second and subsequent frames. Further, since the same gradation level continues, the light transmittance of the liquid crystal panel 8 is as shown in FIG.
As indicated by a broken line A6 in (d), the cumulative response effect gradually increases and becomes constant at the level corresponding to the gradation "4".

In the above embodiment, the comparison circuit 12 compares the image data of this time sent from the A / D conversion circuit 4 with the image data of one frame before read from the image memory 11 and compares the image data D1. .About.D3 and the gradation change signal E are outputted, a sufficient effect can be obtained even if only the gradation change signal is generated and outputted to the segment electrode drive circuit 6 '. In this case, the image data D1 to D3 input to the segment electrode drive circuit 6 '
For this, the output of the A / D conversion circuit 4 may be used as it is.

[0036]

As described above in detail, according to the present invention, in a liquid crystal panel driving device for displaying an image using a liquid crystal panel which responds cumulatively, an image memory for storing one frame of digital image data is provided, and A comparison circuit is provided which compares the levels of the digital image data and the image data read from the image memory with a delay of one frame and outputs a gradation change signal, and the comparison circuit determines that the levels of both comparison data are the same. If it is determined that the normal liquid crystal drive voltage is selected, the electrodes of the liquid crystal panel are driven to display, and if it is determined that the levels of the comparison data are not the same, the liquid crystal drive voltage is higher than the normal liquid crystal drive voltage. By selecting to drive the electrodes of the liquid crystal panel for display, the liquid crystal panel is driven with a high voltage when the image data changes, and It is possible to increase the response speed of the liquid crystal to respond.

According to the present invention, the gradation change signal is output from the comparison circuit, and when the image data of this time and the image data of the previous frame is the same, the image data of this time is output as it is, and the image of this time is output. When the data is larger than the image data one frame before, the maximum value is output as the image data, and when the image data this time is smaller than the image data one frame before, the minimum value is output as the image data and the liquid crystal panel is displayed. Since the display driving is performed, the response speed of the liquid crystal that cumulatively responds can be increased, and a fast moving image can be quickly followed.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a liquid crystal panel drive device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing details of a segment electrode drive circuit in the embodiment.

FIG. 3 is a block diagram showing a configuration of one stage of the analog multiplexer in FIG.

FIG. 4 is a timing chart for explaining the operation of the present invention.

FIG. 5 is a block diagram showing a configuration of a conventional liquid crystal television.

6 is a diagram showing the relationship between the liquid crystal drive voltage composite waveform and the light transmittance of liquid crystal for explaining the operation of FIG.

[Explanation of symbols]

 2 tuner 3 television linear circuit 4 A / D conversion circuit 5 synchronization control circuit 6, 6'segment electrode drive circuit 7 common electrode drive circuit 8 liquid crystal panel 11 image memory 12 comparison circuit 21 data latch clock generation comparison circuit 22 data latch circuit 23 Gradation signal generation circuit 24 Analog multiplexer 25 Blanking control circuit 31-36 Analog switch

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[Procedure amendment]

[Submission date] April 12, 1993

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be amended] Claims

[Correction method] Change

[Correction content]

[Claims]

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0001

[Correction method] Change

[Correction content]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal driving method and a liquid crystal display device for driving a liquid crystal panel used in, for example, a liquid crystal television.

[Procedure amendment 4]

[Document name to be amended] Statement

[Name of item to be corrected] 0005

[Correction method] Change

[Correction content]

FIG. 6 shows the relationship between the liquid crystal drive voltage composite waveform and the light transmittance of the liquid crystal panel 8 when the gradation is "7" and "0". On the other hand, in the above-described conventional liquid crystal panel driving method, as shown in FIG. 6, the liquid crystal panel 8 is driven by simply creating the gradation signals corresponding to the video signals, and thus the liquid crystal panel 8 is driven. There was a problem that the response characteristics could not be improved and it was not possible to deal with fast moving images. The present invention has been made in view of the above circumstances, and provides a liquid crystal driving method and a liquid crystal display device that can speed up the response of a liquid crystal and can quickly follow an image that changes rapidly. The purpose is to

[Procedure Amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0006

[Correction method] Change

[Correction content]

[0006]

SUMMARY OF THE INVENTION The present invention provides a liquid crystal drive for supplying a liquid crystal drive signal according to the size of image data to a liquid crystal panel to drive the liquid crystal panel with a gradation according to the size of image data. In the method, the current image data and the image data one screen before are compared, and if they are equal, a liquid crystal drive signal corresponding to the current image data is supplied to the liquid crystal panel, and the current image data is more than the image data one screen before. If it is larger, the liquid crystal drive signal corresponding to the image data larger than the current image data is supplied to the liquid crystal panel. If the current image data is smaller than the image data of the previous screen, the image smaller than the current image data is supplied. The liquid crystal drive signal corresponding to the data is supplied to the liquid crystal panel. The present invention also provides a liquid crystal driving method for supplying a liquid crystal driving signal according to the size of image data to the liquid crystal panel to drive the liquid crystal panel for display at a gradation according to the size of the image data. The image data of the previous screen is compared, and if they are equal, the liquid crystal drive signal corresponding to the current image data is supplied to the liquid crystal panel, and if they are different, the liquid crystal drive signal corresponding to the image data different from the current image data is sent to the liquid crystal panel. It is something that is supplied.

[Procedure correction 6]

[Document name to be amended] Statement

[Correction target item name] 0007

[Correction method] Change

[Correction content]

Further, according to the present invention, in a liquid crystal display device in which a liquid crystal panel is scanned N times (N is an integer of 2 or more) during one field period of a video signal, the current image data and 1
When the comparison result of the image data before the screen is equal to the comparison result of this device, the liquid crystal drive signal corresponding to the current image data is supplied to the pixel of the liquid crystal panel, and the current image data is the image of the previous screen. When it is larger than the data, the liquid crystal drive signal corresponding to the image data which is larger than the current image data is supplied to the pixel of the liquid crystal panel, and when the current image data is smaller than the image data of the previous screen, the current image data is supplied. And a gradation control means for supplying a liquid crystal drive signal corresponding to image data smaller than the image data to the pixel of the liquid crystal panel. Further, according to the present invention, in a liquid crystal display device that performs gradation display by supplying a gradation signal according to the size of image data to a liquid crystal panel, the image data displayed in each pixel has a bright direction or a dark direction. When it is detected that the image data is changing in the bright direction by the detecting means for detecting which is changing, the liquid crystal panel sends a gradation signal brighter than the gradation of the current image data. And a means for supplying a gradation signal darker than the current image data to the liquid crystal panel when it is detected that there is a change in the dark direction. Furthermore, the present invention provides an image data source,
An image memory for storing one frame of image data supplied from the image data supply source, the current image data supplied from the image data supply source, and the previous image data read from the image memory with a delay of one frame. And a comparison circuit that outputs a gradation change signal and the comparison result of this comparison circuit are equal, the gradation signal based on the image data of this time is output, and the image data of this time is the image data of the previous time. If it is larger than this, a gradation signal larger than the gradation signal based on this image data is output, and if this image data is smaller than the previous image data, it is smaller than the gradation signal based on this image data. And a gradation control means for outputting image data.

[Procedure Amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction content]

[0008]

With the above construction, when the image data changes, the driving is performed so as to emphasize the change in the display, so that the response of the liquid crystal can be speeded up, and the image that changes rapidly can be displayed. It is possible to quickly follow up with.

[Procedure Amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0009

[Correction method] Delete

[Procedure Amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0036

[Correction method] Change

[Correction content]

[0036]

As described above in detail, according to the present invention,
A liquid crystal driving method and a liquid crystal display device for supplying a liquid crystal driving signal according to the size of image data to a liquid crystal panel to drive the liquid crystal panel with a gradation according to the size of the image data, when the image data changes. Since the driving is performed so as to emphasize the change of the display, the response of the liquid crystal can be speeded up, and the image which is changing rapidly can be quickly followed.

[Procedure Amendment 10]

[Document name to be amended] Statement

[Name of item to be corrected] 0037

[Correction method] Delete

Claims (2)

[Claims] 1. A liquid crystal panel drive device for displaying an image using a liquid crystal panel which responds cumulatively, an image memory for storing display digital image data for one frame, a delay of one frame from the digital image data and the image memory. And a comparison circuit that outputs a gradation change signal by comparing the level of the image data read out with the image data to be read, and if the comparison circuit determines that the levels of both comparison data are the same, based on the gradation change signal. The normal liquid crystal drive voltage is selected to drive the electrodes of the liquid crystal panel for display, and when it is determined that the levels of the two comparison data are not the same, the normal liquid crystal drive voltage is determined based on the gradation change signal. A liquid crystal panel drive device, comprising means for selecting a liquid crystal drive voltage and driving the electrodes of the liquid crystal panel to display. 2. The liquid crystal panel drive device according to claim 1, wherein the comparison circuit compares the image data of this time with the image data read from the image memory with a delay of one frame, and changes the gradation. While outputting the signal,
If the image data of this time and the image data of one frame before are the same, the image data of this time is output as it is. If the image data of this time is larger than the image data of one frame before, the maximum value is output as image data, When the image data of this time is smaller than the image data of one frame before, a means for outputting the minimum value as the image data is provided, and the liquid crystal panel is driven to display based on the image data output by this means. Characteristic liquid crystal panel drive device.