JPH08114784A - Liquid crystal display device - Google Patents

Abstract

PURPOSE: To display both of a display of a TV video and an image display of an OA equipment with simple constitution without a flicker. CONSTITUTION: This device is provided with a mode switching means 205 for switching modes between a first mode of performing the image display by a pixel of two levels and a second mode of performing the image display by the pixel of multi-level of three levels or above, a scan voltage application means 102 for successively applying a scan voltage to one piece each among plural scan electrodes 105 only for a first period in the first mode, simultaneously applying the scan voltage to respective M pieces among plural scan electrodes 105 only for a second period M times as long as the first period in the second mode and successively performing such an operation and a signal voltage application means 103 for applying either signal of a first signal voltage and a second signal voltage to respective signal electrodes 106 only for the first period in the first mode and applying alternately the signal of the first signal voltage and that of the second signal voltage to respective signal electrodes 106 each for a first period M times in all during the second period in the second mode.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, which has a particularly simple structure and is capable of displaying a display image by a personal computer or the like and an image which requires more gradation expression than that of the display image.
The present invention relates to a liquid crystal display device capable of mode switching, capable of displaying a higher number of gradations than a conventional one when displaying a gradation image, and reducing flicker to realize good display quality.

[0002]

2. Description of the Related Art Liquid crystal display devices are widely used as display devices for personal OA equipment such as word processors and personal computers, or as display screens for televisions such as pocket televisions by taking advantage of their features such as thinness, light weight and low power consumption. Is becoming popular.

Among them, a liquid crystal display device used as a display device for OA equipment is required to have multi-digit display, high-quality display, and further low cost. As a liquid crystal display device suitable for such an application, there is a simple matrix type liquid crystal display device.

Among them, the STN (Super Twisted Nematic) type liquid crystal display device is capable of multi-digit display and has a simple structure, so that the manufacturing cost can be reduced, so that the cost can be reduced. As a display device for OA equipment such as a required personal computer, the number of pixels is, for example, 640 × 480 dots (VGA) or 640.
The one with × 400 dots is commonly used.

On the other hand, it is required to realize high-quality display at low cost even for a liquid crystal display device which is widely used for personal television which is a so-called consumer electronic device. Since consumer electronic devices generally require severe cost reduction, it is necessary that they have a simple structure and can be manufactured with a high yield. Therefore, a simple matrix type liquid crystal display element is suitable in such an application field.

A liquid crystal display device used for displaying a moving image having gradation expression, such as a personal television, includes:
A TN (twisted nematic) type liquid crystal display device, which can obtain a relatively quick response, is generally used in many cases. The number of pixels is, for example, about 320 × 220 dots, and a relatively small screen size of 6 inches or less is often used.

In recent years, it has been desired to realize a liquid crystal display device used as both the display device for personal OA equipment and the display device for personal television as described above. For example, it is expected to realize a liquid crystal display device which is usually used as a display device for personal OA equipment and which can be used such that a television image is displayed on the same display screen when the OA equipment is not used.

A liquid crystal display device capable of one of these two uses is required to be able to handle image data of OA equipment as well as image display data for displaying a television image.

However, an STN type liquid crystal display module used as a display device of an information processing device such as a personal OA device generally displays by changing its black and white states by switching each pixel ON and OFF. Is formed in a structure corresponding to the binary display function of performing.

Therefore, in order to display a television image requiring gradation expression on an STN type liquid crystal display device generally used in personal OA equipment, a dedicated circuit for gradation display is provided in the liquid crystal display device. It is necessary to provide it separately for the module. Moreover, the display capacity (the number of pixels) of the television image and the display capacity of the display image of the OA device are generally different.

Moreover, in order to express a gradation image on a relatively low-priced simple matrix type liquid crystal display element used in OA equipment, a voltage amplitude modulation (PHM) method or a pulse width modulation (PWM) method is used. Frame decimation (FRC) method is commonly used. However, when displaying a gradation image on such a simple matrix type liquid crystal display element according to the frame thinning method,
There is a problem that flicker frequently occurs in the image due to the change in the state of the liquid crystal cell for each frame, and the display quality is degraded.

Therefore, in order to realize switching between these two different types of display, that is, two modes, with one liquid crystal display device, it is necessary to form a liquid crystal drive circuit according to whichever of the gray scales is required. I have to. When such a circuit is incorporated, there is a problem that the structure of the liquid crystal drive circuit system becomes extremely complicated. For example, a conventional liquid crystal drive circuit system has a so-called V which is a memory for storing image data.
-A RAM is used, but this V-RAM must be provided in the liquid crystal display device, one for each of the two different modes. As a result, it is difficult to reduce the size and cost of the liquid crystal display device.

Further, without making such a system change,
Using the conventional gradation display method (frame thinning method),
There is a problem that flicker frequently occurs in the displayed image.

Further, the liquid crystal module itself must be provided with a function of displaying gray scales. In this case, it is necessary to use a dedicated gray scale display driver IC for driving the liquid crystal display element. However, there is a problem that the cost (and the price as a product) becomes expensive.

[0015]

The present invention has been made to solve the above problems, and its purpose is to:
Provided is a liquid crystal display device capable of displaying both an image of a television image and an image of an OA device by a single device by extremely simple and inexpensive means and capable of displaying a high-quality gradation image without flicker. To do.

[0016]

A liquid crystal display device according to the present invention comprises a plurality of scanning electrodes running in a first direction, wherein a scanning voltage or a non-scanning voltage is applied by switching. And a second perpendicular to the first direction
A plurality of signal electrodes that run in the direction of, and are sandwiched between a plurality of drive electrodes, to which either the first signal voltage or the second signal voltage is applied by switching, and the scan electrodes and the signal electrodes. Mode switching means for switching between a liquid crystal layer, a first mode for displaying an image with pixels of two gradations, and a second mode for displaying an image with pixels of three or more gradations; Scanning voltage applying means for switchingably applying the scanning voltage and the non-scanning voltage to a scanning electrode,
In the first mode, the scan voltage is sequentially applied to each of the plurality of scan electrodes only for a first period, and in the second mode, the scan voltage is M times the first period. Only in the second period, each M of the plurality of scan electrodes
Scanning voltage applying means for simultaneously performing this operation in addition to the book and driving voltage applying means for switchingably applying the first signal voltage and the second signal voltage to each of the signal electrodes. In the mode, the signal of either the first signal voltage or the second signal voltage is applied to each of the signal electrodes only during the first period, and in the second mode, during the second period, A drive voltage applying unit that selects one of the two signals of the first signal voltage and the second signal voltage for each signal electrode and applies the signal M times for each of the first periods. Configured as equipped.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION A liquid crystal display device of the present invention is a first device for displaying an image for a display device such as OA equipment or a display terminal.
The liquid crystal drive circuit system is formed so that the mode and the second mode for displaying an image having a gradation expression such as a television image can be switchably selected. Then, basically by using a simple matrix type liquid crystal display element made corresponding to binary display, both the display in the first mode and the display in the second mode have good gradation reproducibility and flicker. There is no high quality.

In the liquid crystal display device of the present invention, a liquid crystal display element whose basic structure is formed corresponding to binary display is used, but in the second mode, the conventional area gray scale method or It is driven based on a new driving method unique to the present invention, which is different from the gradation display method by the voltage amplitude modulation method, the gradation display method by the voltage pulse width modulation method, the gradation expression method by the frame thinning method, and the like.

That is, the liquid crystal display device of the present invention is the second
In the mode (1), scan data for generating a scan voltage waveform in which M scan electrodes that are adjacent to each other are collectively selected at the same time by shifting the scan electrodes by N scans every N scan selection periods of M> N Is formed by the scan data generating circuit and is supplied to the scan driver circuit.

On the other hand, the image signal data generation circuit applies the gradation image signal voltage of digital format to the liquid crystal cell every scanning period and performs gradation display by averaging in the N scanning selection period. Is generated and is supplied to the signal driver circuit.

The scan driver circuit collectively selects N scan electrodes adjacent to each other in a scan selection period at the same time. That is, a scanning pulse is applied to the N adjacent scanning electrodes at once to bring them into a selected state. On the other hand, on the side of each signal electrode, an image signal voltage for performing gradation expression is formed from the signal driver circuit based on the image signal data based on the average of the lighting states in the M scan selection period as described above, and this is applied to the signal electrode. Is applied. At this time, the liquid crystal application voltage applied to each pixel in the tolerance portion between the M scan electrodes in the scan selection state and each signal electrode acts as an average of the voltages applied during the M scan selection period. Therefore, it is possible to display an image having a gradation expression of M + 1 gradation including a completely lit state and a completely unlit state.

Further, according to the present invention, the M scanning electrodes adjacent to each other are collectively brought into the scanning selection state at a time,
This is equivalent to the fact that the number of scanning lines is substantially reduced as compared with the first mode, and the response of the liquid crystal can be made substantially faster. This effect is obtained by setting M in which M adjacent scan electrodes are collectively brought into a scan selected state at a time to M> N.
It is possible to obtain the effect by performing scanning by sequentially shifting N scanning lines for each scanning selection period, or M
The effect can be obtained even when scanning is performed by sequentially shifting the scanning lines by M scanning lines for each scanning selection period.

Therefore, such a liquid crystal is suitable for displaying a moving picture of a television image, which requires a good response of the liquid crystal, and generally has a smaller number of scanning lines than the display image of the OA equipment. That is, when the number of scanning electrodes of the liquid crystal display element used is different from the effective number of scanning lines of the image signal of the television, the above-mentioned M and N are set to appropriate values so that the effective television image is obtained. It is possible to perform scanning suitable for the number of scanning lines. Moreover, at this time, according to the present invention, in particular, scanning is performed by shifting the selection state by N scanning lines in every N scanning selection period while collectively bringing the M scanning electrodes adjacent to each other into the scanning selection state at the same time. Then, the change in the lighting state of the pixels of the adjacent scanning lines becomes smooth in the preceding and succeeding scanning selection periods.
That is, by setting the condition of M> N, MN scan electrodes are selected in an overlapping manner in one scan selection period. Since such a selected state of the scan electrodes is sequentially scanned in each scanning selection period, a change in luminance between pixels selected in each frame period,
That is, the change in luminance within one screen becomes extremely smooth.

Further, in the display by the frame thinning method, flicker frequently appears on the screen, but according to the present invention, such flicker is effectively eliminated, and a stable high-quality image without flicker is displayed. It becomes possible to do.

In the second mode, since M scan electrodes are simultaneously selected at one time in each scan selection period as described above, the first scan electrodes are simply line-sequentially scan-selected. The driving duty ratio of the liquid crystal becomes substantially larger than that in the mode (1).

Therefore, when the second mode is selected, the liquid crystal drive voltage waveform is optimized corresponding to the value of M.

Here, the peak value (absolute value) of the scanning voltage waveform
Is A and the peak value (absolute value) of the signal voltage waveform is B,
A + B is defined as the liquid crystal drive voltage V _OP . Also, B / (A
+ B) is defined as the bias ratio 1 / b.

First, V _OP when the second mode is selected
Is smaller than V _OP when the first mode is selected, the effective value of the liquid crystal applied voltage due to the change of the drive duty ratio between the two modes is made uniform. If the bias ratio 1 / b when the second mode is selected is lower than the bias ratio 1b when the first mode is selected, both the first mode and the second mode are set. It acts to make the effective value of the liquid crystal applied voltage in the mode uniform. As a result, the brightness and contrast characteristics of the display image can be made uniform.

The control of the bias ratio of the image signal voltage as described above is preferably set to a theoretically optimum value for each of the first mode and the second mode.

Such a theoretically optimum value means that the bias ratio in the first mode is 1 / (L ^1/2 +
1), and the bias ratio of the second mode is 1 /
It is {(L / M) ^1/2 +1}. By setting in this way, the ratio (Vs / Vns) between the effective voltage value Vs for turning on the liquid crystal display element and the effective voltage value Vns for displaying OFF is set to the first value. And each of the second modes can be maximized. Therefore, by setting such a bias ratio, it is theoretically possible to obtain the largest contrast ratio and brightness in each mode. Although the theoretical optimum value of the above-mentioned bias ratio is as described above, it is desirable to set it within the tolerance ± α = 45% as a practical allowable range.

This is because it is necessary to adjust within the allowable range α according to the specifications of the liquid crystal display panel to be specified. Liquid crystal display panels have different capacitances depending on the liquid crystal material used, the size of the panel, the gap, and the like. This is to adjust this bias by adjusting the bias ratio to obtain a uniform display.

Examples of the liquid crystal display device of the present invention will be described below.
It will be described in detail with reference to the drawings. (Embodiment 1) FIG. 1 is a diagram schematically showing a schematic structure of a liquid crystal display device according to a first embodiment of the present invention. This liquid crystal display device includes a liquid crystal display element 101 and the liquid crystal display element 101.
A liquid crystal module 104, the main part of which is composed of a scan driver circuit 102 and a signal driver circuit 103 for driving the liquid crystal module 104, and scan data and image data for driving the liquid crystal display element 101 to display an image. A data generation circuit 201 for supplying the scan driver circuit 102 and the signal driver circuit 103 is provided.

The data generation circuit 201 is a TV tuner / video input circuit 20 for generating a so-called television video signal as gradation image data having an analog gradation expression.
2 and an ADC for analog-digital converting the video signal supplied from the TV tuner / video input circuit 202
A circuit 203, a microprocessor 204 for generating image data such as a microcomputer and a word processor, a mode switching circuit 205 for selecting the output of either the TV tuner / video input circuit 202 or the microprocessor 204, and this mode switching An image signal data generation circuit 206 which is supplied with the data selected by the circuit 205 and generates image signal data based on the data.
And a scan data generation circuit 207 for generating scan data.
Is provided.

The data generation circuit 201 is a TV tuner /
A television image signal for displaying a television image, that is, grayscale image data in an analog format, which is supplied from the video input circuit 202, and gradation image data output from the microprocessor 204 for forming an image of a computer or a word processor, for example, a number or The mode switching circuit 205 selects either one of the digital format data for displaying a character display and the like. In this way, it has a function of switching between the first mode for displaying images on a computer or the like and the second mode for displaying television images.

When the first mode is selected,
Data is supplied from the microprocessor 204 to the image signal data generation circuit 206 and the scan data generation circuit 207 via the data bus. Image signal data generation circuit 20
6. The scan data generation circuit 207 generates image signal data and scan data based on the data. Then, the image signal data based on this data is supplied to the signal driver circuit 1
03, scan data to the scan driver circuit 102,
Supply each.

When the scan data is supplied, the scan driver circuit 102 applies a scan selection voltage to each of the scan electrodes selected from the scan electrodes 105 during the scan selection period.

On the other hand, when the image data is supplied to the signal driver circuit 103, the signal driver circuit 103 supplies the signal voltage to each signal electrode 106 in synchronization with the scanning voltage. Then, in the liquid crystal display element 101, these scanning voltage and signal voltage are superimposed and applied as a liquid crystal applied voltage, and the liquid crystal cell for each pixel is driven to display an image by a microcomputer or word processor on the screen of the liquid crystal display element 101. Is displayed in.

On the other hand, when the second mode for displaying a television image is selected by the mode switching circuit 205, the analog format data generated by the TV tuner / video input circuit 202 is converted by the ADC circuit 203 into analog / digital data. After being converted and converted into digital format data, the converted data is supplied to the image signal data generating circuit 206 and the scanning data generating circuit 207 via the data bus.

At this time, the scan data generated by the scan data generating circuit 207 is performed by shifting N adjacent scan electrodes simultaneously by N shifts in every N horizontal periods of M> N. It generates scan data and supplies it to the scan driver circuit 102. on the other hand,
The image signal data generation circuit 206 generates image signal data that expresses gradations on the average of M scan selection periods, and supplies this to the signal driver circuit 103. Then, the scan driver circuit 102 and the signal driver circuit 103 respectively form a scan voltage and a signal voltage based on the supplied scan data and image data, and apply them to the scan electrode 105 and the signal electrode 106, respectively. In this way, the liquid crystal display element 101 is driven, and an image having gradation expression is displayed by averaging the lighting state of each pixel in the M scan selection period.

The general structure and operation of the liquid crystal display device of the first embodiment according to the present invention are as described above.
The detailed structure and operation will be described.

The TV tuner / video input circuit 202 and the microprocessor 204 are arranged outside the liquid crystal display device according to the present invention, and the TV tuner and the data bus of another microcomputer are arranged outside this liquid crystal display device. Analog data and digital data,
You may make it supply to the liquid crystal display device of this invention.

The ADC circuit 203 performs analog-to-digital conversion on the input analog format data and converts it into a digital format.
It is a circuit to convert to. Therefore, it goes without saying that it is possible to use a conventional AD converter, but particularly in this embodiment, an AD converter circuit as shown in FIG. 2 was used. The AD conversion circuit shown in the figure is digitally converted from the voltage of the analog format video signal input from the TV tuner / video input circuit 202 in descending order of the voltage, and is assigned to each step voltage up to the MSB. Is output. Such a circuit has a remarkable point that it has an extremely simple structure and can be manufactured at low cost. Further, by using this circuit, the image data generating circuit can be simply a frame memory or a circuit for converting data into a data memory.

The mode switching circuit 205 is a switching circuit, and is connected from the TV tuner / video input circuit 202 to the ADC.
Of the data input via the circuit 203 and the binary image data supplied from the microprocessor 204,
A switch circuit for selecting one. As this circuit, any circuit may be used as long as it has the above-mentioned function as a switch circuit.
It goes without saying that the switching operation of No. 5 may be performed by inputting a mode switching signal input to the mode switching circuit 205, or may be switched by using a mechanical switch.

The image signal data generation circuit 206 is mainly composed of a frame memory (not shown) corresponding to the number of pixels of the liquid crystal display element 101 and a timing circuit (not shown) for controlling data writing / reading. ing. It operates so as to write the AD-converted data to a predetermined address of the frame memory. Then, the data written in the frame memory is read out, and this is read by the liquid crystal module 1
04 to the signal driver circuit 103.

On the other hand, the scan data generating circuit 207 generates scan data which determines the scan selection state of the scan electrode 105 in synchronization with the timing signal and supplies it to the scan driver circuit 102.

FIG. 3 is a diagram schematically showing the structure of the liquid crystal module 104.

As is clear from FIG. 3, the liquid crystal display element 101 is formed in a structure in which the scanning electrodes 105 and the signal electrodes 106 are arranged in a matrix and the liquid crystal composition (not shown) is sandwiched between the scanning electrodes 105 and the signal electrodes 106. Has been done. The liquid crystal display element 101 is an STN type liquid crystal display element. Screen size is A4 size, display capacity (pixel number) is 640x
It is 480 dots. This STN type liquid crystal display element has a cell gap of about 7 μm, and is provided with an alignment film made of a polyimide subjected to a rubbing alignment treatment so that liquid crystal molecules are twisted by 240 ° in the cell of the liquid crystal display element. As the liquid crystal composition, ZLI-2293 manufactured by Merck Ltd. was used.
Further, the scanning electrodes 105 and the signal electrodes 106 are formed by using ITO transparent electrodes. This liquid crystal display element 101
The optical phase compensation cell is attached on the liquid crystal display element 101 in order to eliminate the coloring of the display by the STN type liquid crystal at the time of performing the black and white display, and it is black when the voltage is not applied and white when the voltage is applied. In this embodiment, the display is set so as to be captured.

The scan driver circuit 102 forms a scan voltage using four potentials V0, V1, V4, and V5 based on the scan data. Further, the signal driver circuit 103 forms a signal voltage using the potentials V0, V2, V3, and V5 based on the image signal data. These potentials V0 to V5 are created by dividing the input DC power supply voltage V _DD in the liquid crystal drive voltage generating circuit 107 using the voltage dividing circuit as shown in FIG. The liquid crystal drive voltage generation circuit 107 receives the input power supply voltage V _DD from the resistors R4 and R4.
The potentials V0 to V5 are generated by voltage division by 5, and these potentials are output via the buffers 108, respectively. Then, among these output potentials, as described above, V0, V
1, V4, V5 to the scan driver circuit 102, V0, V
2, V3, and V5 are supplied to the signal driver circuit 103, respectively. These output potentials V0, V1, V2, V3,
V4 and V5 are applied to the liquid crystal display element 101 as liquid crystal application voltages having a waveform as shown in FIG. 5 in the first mode.

In the scan driver circuit 102, the scan control signal (F
P: receiving a frame pulse), the potential (V0, V1, V
4, V5), a potential corresponding to the scanning data is selected and applied to each of the 240 scanning electrodes 105 Y1 to Y240.

The main part of the scan driver circuit 102 is shown in FIG.
As shown in FIG. 5, a shift register latch 109 that sequentially transfers scan data internally, and a scan pulse (V0 and V5 when polarity inversion) or scan non-selection, which is controlled by the shift register latch 109, is selected. And a switch section 110 for selecting the potential (V4 and V1 when the polarity is inverted).

The shift register / latch 109 is an FP
When (frame pulse) is received as basic scan data, the scan data from outputs Y1 to Y240 are sequentially transferred to 240 register elements (not shown) in response to the clock CP ', and LP (latch pulse) Receiving the signal,
The output voltages of the outputs Y1 to Y240 are output. This operation is the same when the second mode is selected.

Inside the switch section 110, switch elements (not shown) connected to each of the 240 scan electrodes 105 are arranged in a row. Each of the switch elements performs a switching operation based on the scan data transferred from each of the 240 register elements provided inside the shift register latch 109. That is, each switch element of the switch unit 110 selects the potential V0 (or V5 when the polarity is inverted) and outputs it to the scan electrode 105 when the scan data in the shift register / latch 109 is “select” data. . In the case of “non-selected” data, the potential V4 (or V1 when the polarity is inverted) is selected and output to the scan electrode 105. Thus, the scanning voltage as shown in FIG. 5A is applied to the scanning electrode 105.

On the other hand, the signal driver circuit 103 receives the image signal data input from the image signal data generation circuit 206 and selects the potential corresponding to the image signal data from the potentials V0, V2, V3 and V5. , X1 to X640
A signal voltage is applied to each of the 640 signal electrodes 106. The signal driver circuit 103, as shown in FIG.
A shift register 111 in which register elements (not shown) for sequentially transferring image signal data are arranged in a row, a data latch 112 for holding the sequentially transferred image signal data in parallel at a predetermined timing, and a hold The main part is formed of a switch part 113 for selecting an output potential based on the image data.

When the shift register 111 receives the image signal data (hereinafter referred to as "DATA" in the text), the D
DAT corresponding to the signal electrodes 106 (X1 to X640) by the clock pulse (CP) for transferring ATA
A is sequentially transferred to each register element. Then, the data latch 112 receives the latch pulse (LP) and outputs X1.
Corresponding to all signal electrodes 106 from 1 to X640
Hold ATA in parallel. And switch unit 1
13 is D based on the held DATA.
When the ATA is data for selecting the ON state, the selection voltage V5 and the polarity inversion V0 are selected. Also DATA
Is the non-selection voltage V3 when the data is for selecting the OFF state.
And the voltage V2 at the time of polarity reversal is selected. Thus, FIG.
An image signal voltage as shown in (b) is applied to each signal electrode 106.

In this manner, when the scanning voltage is applied to the scanning electrode 105 and the signal voltage is applied to the signal electrode 106, the liquid crystal layer () sandwiched at the intersection of the scanning electrode 105 and the signal electrode 106 ( The voltage waveform applied to (not shown) is a liquid crystal applied voltage having a waveform as an example shown in FIG. In FIG. 5C, the waveform is inverted every frame for the sake of explanation, but the polarity is generally inverted every 10 to 20 scanning times.

As is well known, the polarity inversion driving method is a driving method which is performed by using an AC liquid crystal applied voltage in order to prevent deterioration of the liquid crystal composition due to application of a DC voltage component to the liquid crystal layer. The switch section 110 in the scan driver circuit 105 and the switch section 113 in the signal driver circuit 103 described above are formed to be controlled by the polarity inversion signal (FR) to invert the polarity at a constant cycle.

The waveform of the scanning voltage formed by the scanning driver circuit 102 and the waveform of the image signal voltage formed by the signal driver circuit 103 in this way are shown in FIG. 6 as an example of the first mode. FIG. 7 shows an example of the case of the second mode. In both figures, the output waveform shows only the voltage waveform on one side (in one frame period) for the sake of simplification of the drawing and simplification of the description.

In the first mode, as shown in FIG. 6, the scanning electrodes 105 are line-sequentially scanned one by one, and in synchronization with this, V5 is supplied to the signal electrodes 106 if selected, and V3 is supplied if not selected. To be done. In FIG. 6, white and black images can be displayed as shown at the right end. Such binary display is suitable for image display such as character or number character display of an information processing device such as a personal computer. Further, it is suitable when performing gradation expression by these frame thinning methods.

On the other hand, in the second mode, as shown in FIG. 7, the scanning electrodes 105 collectively bring adjacent M lines into a scanning selection state for M scanning selection periods at a time, sequentially for each N scanning selection period. Scan data that is shifted by N scan electrodes is supplied to the scan driver circuit 102.
In this embodiment, M = 4 and N = 2 as shown in FIG. An image signal is supplied to the signal electrode every scanning selection period.

FIG. 8 shows a processing flow of image signal supply in the second mode. As shown in step 801, the video signal of the television for one field (needless to say, one screen is formed by two fields) supplied from the TV tuner / video input circuit 202 is as shown in step 802. It is converted from analog to digital (ADC), transmitted through the data bus in FIG. 1, and supplied to the image signal data generation circuit 206 and the scan data generation circuit 207, respectively. In the image signal data generation circuit 206 and the scan data generation circuit 207,
As shown in step 803, the unit scanning time M frames of the number M of simultaneously selected scanning electrodes 105 and the scanning transition interval N are set. In this way, the scanning electrodes 105 are simultaneously selected by grouping M adjacent M electrodes, and these M scanning electrodes 105 are simultaneously selected. Then, the image signal voltage is supplied thereto M times for each scanning selection period, so that the difference between the voltages applied to the scan electrode 105 and the signal electrode 106 is applied to the liquid crystal. As a result, the liquid crystal application voltage applied to the liquid crystal cell of each pixel becomes an average value of the M scan selection period in every M scan selection period. In this embodiment, as described above, M = 4 and N =
It is set to 2.

The image displayed by the voltage waveform in the second mode thus formed is a multi-tone image.

Moreover, four scanning electrodes 1 adjacent to each other
05 are collectively set so as to be simultaneously brought into the scan selection state for four scan selection periods and are sequentially shifted every two scan selection periods. Therefore, MN = number of lines is set for each scan selection period. Since the scanning electrodes 105 are overlapped and selected, one screen formed by one cycle of this scanning has an extremely smooth change in brightness between adjacent pixels. . as a result,
It has become possible to display a screen that requires multi-gradation expression such as a television image in multi-gradation and extremely smoothly even if a liquid crystal display element that originally can only display binary values is used.

As described above, in the liquid crystal display device according to the present invention, the display screen for displaying the image information of the information processing equipment (OA equipment) such as a personal computer by the changeover switch for switching the first and second modes. You can switch the mode with the TV screen that displays the TV image,
In addition, it is possible to realize display with good display quality in each mode.

In addition, the liquid crystal display device of the present invention has a multi-level structure due to the addition of an extremely simple circuit even if the liquid crystal display device of the basic design that can display only the most general binary of black and white is used. It has the feature that key display is possible.

(Second Embodiment) In the second embodiment, in the liquid crystal display device of the first embodiment, the scan data generating circuit 207, the scan driver circuit 102, the image signal data generating circuit 206, the signal driver. The circuit structure of the circuit 103 is changed to correspond to M = N = 2. The structures and functions of the other parts are the same as those in the first embodiment. In the description of this embodiment and FIG. 9, the same numbers and names are used for the same parts as in the first embodiment for the sake of simplicity. In the liquid crystal display device of the second embodiment as described above, the display in the first mode is performed with the liquid crystal applied voltage having the same waveform as that of the first embodiment.

The display of the gradation image in the second mode is as follows.
As shown in FIG. 9, two scan electrodes 10 adjacent to each other are provided.
It is set so that the scans in which 5 are collectively brought into the scan selection state at the same time are sequentially shifted by two scan electrodes every two scan selection periods. For example, the liquid crystal display device of this embodiment is suitable for displaying the image of the consumer TV having about half the number of scanning lines of the image of the personal computer in the second mode. At this time, the number of scanning lines is not exactly 1/2, but it goes without saying that the error may be adjusted, for example, in the vertical blanking period.

Since the average voltage of the N scanning selection period is applied to each pixel of the liquid crystal display device of the second embodiment having such a structure, a gradation image can be displayed by this. Moreover, it is possible to switchably display images of two modes with different numbers of scanning lines on the same one liquid crystal display device.

(Third Embodiment) In the third embodiment, in the liquid crystal display device of the second embodiment, the scan data generating circuit 207, the scan driver circuit 102, the image signal data generating circuit 206, the signal driver. The circuit structure of the circuit 103 is changed so as to correspond to M = N = 3. The structures and functions of the other parts are the same as those in the first and second embodiments. In the description of this embodiment and FIG. 10, the same numbers and names are used for the same parts as those in the first and second embodiments for the sake of brevity. In the liquid crystal display device of the third embodiment, the first mode display is the first mode display.
The liquid crystal applied voltage having a waveform exactly the same as that in the above embodiment is used.

Then, as shown in FIG. 10, the liquid crystal applied voltage for displaying the gradation image in the second mode is set to the scan selection state for three scan selection periods at the same time by the three scan electrodes 105 adjacent to each other. It is set so that the subsequent scanning is sequentially shifted by three scanning electrodes for every three scanning selection periods.

The liquid crystal display device of the third embodiment as described above is for consumer use having about one-third the number of scanning lines as compared with the number of scanning lines of a high-definition image such as CG (computer graphics). It was suitable for displaying the TV image in the second mode. At this time, the number of scanning lines is not exactly 1/3, but it goes without saying that the error may be adjusted, for example, for each vertical blanking period, as in the second embodiment.

Since an average voltage of three scanning selection periods is applied to the liquid crystal cell of each pixel of the liquid crystal display device of the third embodiment having such a structure, gradation display can be performed by this. Moreover, it is possible to switchably display images of two modes with different numbers of scanning lines on the same one liquid crystal display device.

Moreover, the AD shown in FIG. 2 in the first embodiment.
The voltage division ratio at R1, R2, and R3 inside the C circuit 203 is
The liquid crystal used in the liquid crystal display element 101 is adjusted so as to match γ (steepness of electric and optical curves), and M is set to 3 or more, for example, 4, 5, 6, ... The display can be displayed with more gradation than in the case of the second embodiment.

(Embodiment 4) In the fourth embodiment, in the liquid crystal display device of the first embodiment, as shown in FIG.
As shown in FIG.
Voltage changeover switch 110 for switching between inserting the electric resistance R55 in the circuit between the second mode and the second mode or biasing the electric resistance R55 with the switch without passing through the electric resistance R55.
The addition of 1 is a change from the liquid crystal display device of the first embodiment. The structures and functions of the other parts are the same as those in the first embodiment. A feature of the liquid crystal display device of the fourth embodiment is that the amplitude of the liquid crystal applied voltage can be switched for each mode by switching the voltage changeover switch 1101 for each mode. In the description of this embodiment and FIG. 11, the same numbers and names are used for the same parts as in the first embodiment for the sake of brevity.

The voltage changeover switch 1101 receives the same mode changeover signal as that inputted to the mode changeover circuit 205, and is controlled by this mode changeover signal to generate the first changeover signal.
When the mode is selected, the switch is turned on and the power supply voltage V _OP is directly input to the voltage dividing circuit.

On the other hand, when the second mode is selected, the switch is turned off, and the power supply voltage V _DD is input to the voltage dividing circuit via the electric resistance R55. Therefore, in the second mode, the amplitude of the voltage output from the voltage dividing circuit at the subsequent stage, that is, the voltage output from the liquid crystal drive voltage generating circuit 107, decreases in proportion to the amount of voltage drop due to the electric resistance R55.

In this way, the amplitude of the liquid crystal applied voltage can be switched to a different amplitude for each mode, and the maximum amplitude of the liquid crystal applied voltage in the second mode is set to be lower than that in the first mode. It was possible to make the luminance characteristics of the display image uniform in.

The technique of the fourth embodiment for controlling the amplitude of the liquid crystal applied voltage for each mode as described above is the liquid crystal of the first embodiment as an example shown in the fourth embodiment. It goes without saying that the present invention can be applied to the liquid crystal display devices of the second and third embodiments as well as the display device.

(Embodiment 5) In the fifth embodiment, the liquid crystal display device of the first embodiment described above is used as shown in FIG.
As shown in FIG. 2, an electric resistance R5 ′ is provided in the voltage dividing circuit of the liquid crystal drive voltage generating circuit 107, and the electric resistance R5 is connected in series in the voltage dividing circuit in the first mode and the second mode. The difference from the liquid crystal display device of the first embodiment is that a voltage dividing switch 1201 for switching between connecting and disconnecting R5 'is additionally provided. The structures and functions of the other parts are the same as those in the first embodiment. It is possible to switch the bias ratio of the liquid crystal applied voltage to different amplitudes for each mode by switching the voltage dividing switch 1201 for each mode. It is a feature.
In the description of this embodiment and FIG. 11, the same numbers and names are used for the same parts as in the first embodiment for the sake of brevity.

The voltage division changeover switch 1201 receives the same mode changeover signal as that inputted to the mode changeover circuit 205, and is controlled by this mode changeover signal to generate the first voltage changeover signal.
When the mode is selected, the switch is turned on, the power supply voltage V _DD bypasses the electric resistance R5 ', and is output as in the first to fourth embodiments, between V2 and V3. Is divided by R5. The bias ratio of the liquid crystal applied voltage output from the liquid crystal drive voltage generation circuit 107 in the first mode is 1/17.

On the other hand, when the second mode is selected, the switch is turned off, and the power supply voltage V _DD is divided between the output terminals V2 and V3 by the electric resistance R5 and the electric resistance R5 '. To be done. Therefore, in the second mode, a voltage having a bias ratio lower than that in the first mode is output from the liquid crystal drive voltage generation circuit 107. In the present embodiment, the bias ratio of the liquid crystal applied voltage output from the liquid crystal drive voltage generation circuit 107 in the second mode is 1/33.

As described above, the bias ratio of the liquid crystal applied voltage can be switched to a different value for each mode, and the bias ratio of the liquid crystal applied voltage in the second mode is set to be lower than that in the first mode. The brightness characteristics of the display image in the mode could be made uniform.

The technique of switching the bias ratio for each mode in the fifth embodiment is applied only to the liquid crystal display device of the first embodiment as shown as an example in the fifth embodiment. It is not limited to what is possible. In addition to this, it goes without saying that the present invention can be applied to the liquid crystal display devices of the second to fourth embodiments.

(Embodiment 6) In the liquid crystal display device of the sixth embodiment, the liquid crystal display device of the fifth embodiment is provided with R6 and a voltage changeover switch 1301 for biasing it as shown in FIG. In addition, the bias ratio in the first mode is 1 / (L ^1/2 +1) and the bias ratio in the second mode is 1 / {(L / M) ^1/2 +1}.
The liquid crystal drive voltage generation circuit 107 for outputting the liquid crystal applied voltage as described above is modified.

By setting in this way, the effective voltage value Vs for turning on the liquid crystal display element and OFF
Of the effective voltage value Vns for displaying
/ Vns) can be maximized in each of the first and second modes. Therefore, by setting such a bias ratio, it is possible to obtain the largest contrast ratio and brightness in each mode. Here, in a practical liquid crystal display device, it is practically effective if it is set in a range of ± 45% with the above theoretical value as the central value.

In the present embodiment, the bias ratio of the liquid crystal applied voltage in the first mode is set to the number of scan electrodes L = 2.
In the case of 40, the bias ratio 1 / b = 1/21, which gives the maximum contrast according to the above theoretical formula, and the bias ratio of the liquid crystal applied voltage in the second mode is 1 / b = 1/1.
It was set to 2.5.

By thus setting the optimum bias ratio for each mode, high-quality images having better contrast characteristics than those of the liquid crystal display devices of the first and fourth embodiments can be obtained. It can be displayed in each of the two modes.

In the liquid crystal display device according to the present invention described above, attention is paid to the fact that the number of scanning lines in the second mode is substantially L / M with respect to the first mode. Set the bias ratio that can take the contrast ratio of.
7 and 4 show a liquid crystal drive voltage generation circuit. This circuit has the function of receiving the mode switching signal and changing the bias ratio. Each of the voltage levels V0 to V5 is the liquid crystal drive voltage VOP.
Is given by resistance division. The resistors R3 and R3 'that divide the voltage between V2 and V3 are resistors that determine the bias ratio. According to the present invention, the transistor switch 2 whose ON / OFF is controlled by the mode switching signal causes
You are getting one bias ratio. When the mode switching signal indicating the second mode is received, the transistor switch 2 is turned on, the resistance dividing the voltage between V2 and V3 is only R3, and the bias ratio 1 / max that can obtain the maximum contrast ratio is obtained.
It is set to {(L / M) ^1/2 }. Further, when receiving the mode switching signal indicating the first mode, the transistor switch is turned on and the resistor R3 'is short-circuited, so that V2 and V3.
Bias ratio 1 / {(L +
1) ^1/2 } is set.

When the liquid crystal drive voltage is set in this way, both Vs and Vns in the second mode become larger than in the first mode. Therefore, VOP is controlled by the resistor R5 and the switch 1 controlled by the mode switching signal. The function to switch the size of is provided. Switch 1 is turned off in the first mode
N, in the second mode, the switch 1 is turned off so that the VOP in the second mode is smaller than the VOP in the first mode.

(Embodiment 7) In the above description, the case where one whole screen is displayed in the first mode or the second mode has been described.
Display in the first or second mode can be mixed on one screen.

FIG. 14 shows a case where the left side area A of the liquid crystal display element 101 is displayed in the second mode and the right side area B is displayed in the first mode. In this case, the scan driver circuit 102 (A) and the signal driver circuit 103 (A) are provided corresponding to the left area A, and the scan driver circuit 102 corresponding to the right area B.
(B) and a signal driver circuit 103 (B) are provided. The scan driver circuit 102 (A) and the signal driver circuit 103 (A) include the data generation circuit 201.
From, respectively, the scan data SCD _{2 in} the second mode and the signal data SGD _{2 in} the second mode are added. Further, the scan driver circuit 102 (B) and the signal driver circuit 103 (B) receive the scan data SCD _{1 in} the first mode and the signal data SGD ₁ in the first mode from the data generation circuit 201, respectively. I can get it. As a result, as described above, the left area A of the liquid crystal display element 101 is displayed in the second mode, and the right area B is displayed in the first mode.

The data output from the data generating circuit 201 is set to an appropriate value so that the liquid crystal display element 1
It is also possible to display the left side area A of 01 in the first mode and display the right side area B in the second mode.

FIG. 15 shows an example in which the upper area A and the lower area C of the liquid crystal display element 101 are displayed in the first mode and the central area B is displayed in the second mode.

In this example, one signal driver circuit 103 is provided for the entire liquid crystal display element 101, and the upper, middle and lower regions A, B and C are provided.
Scan driver circuits 102 (A) and 102, respectively
(B) and 102 (C) are provided. These signal driver circuit 103, scan driver circuit 102 (A)-
102 (C), signal data SGD and scan data SCD ₁ , SCD ₂ , SDC ₁ in the first, second, and first modes are added from the data generation circuit 201. As a result, as described above, the first, second, and third regions A, B, and C of the liquid crystal display element 101 respectively have
Display in the second and first modes is performed.

Although FIG. 15 shows an example in which the second mode is displayed in the center of the screen of the liquid crystal display element 101,
It can also be displayed above and below. Thus, at any position, display can be performed in any one of the first and second modes.

The data generation circuit 201 shown in FIGS. 14 and 15.
Details of A and 201B are shown in FIGS. 16 and 17, for example.

In particular, as shown in FIG. 17, the data generation circuit 201B includes a mode switching timing generation circuit 208. By switching the mode switching circuit 205 by this timing generation circuit 208, for example, FIG.
As shown in, the output OUT2, OUT3, and OUT4 respectively output the scan data SCD1, SCD2, and SCD1 in the first, second, and first modes. As a result, as shown in FIG. 15, the areas A, B, and C can be displayed in the first, second, and first modes, respectively.

As described above, according to the embodiment of the liquid crystal display device of the present invention, not only the same mode is displayed on all screens, but also the first and second modes are displayed on the left and right sides of the screen. It is also possible to display them in a mixed manner at the top and bottom.

Although the embodiments of the present invention have been described above in the case of a liquid crystal display element, they can be applied to driving and lighting other display devices such as an EL display and a plasma display.

[0099]

As described above in detail, the liquid crystal display device of the present invention has a second mode for displaying an image such as a television image and a character output of a computer (display of characters and numbers). ) And a first mode for displaying an image as described above). In the second mode, a multi-tone image can be displayed extremely smoothly without flicker.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic structure of a liquid crystal display device of a first embodiment.

FIG. 2 is a diagram showing a structure of an ADC circuit.

FIG. 3 is a diagram showing an overall circuit structure of a liquid crystal display device of the present invention.

FIG. 4 is a diagram showing a liquid crystal drive voltage generating circuit of the liquid crystal display device of the first embodiment.

FIG. 5 is a diagram showing an example of waveforms of a scan voltage and a signal voltage in the first mode.

FIG. 6 is a diagram showing an example of a scanning voltage waveform and a signal voltage waveform for displaying a binary representation image in the first mode.

FIG. 7 is a diagram showing an example of a scan voltage waveform and a signal voltage waveform for displaying a grayscale image at an average of voltages in the M scan selection period for each pixel in the second mode.

FIG. 8 is a diagram schematically showing a processing flow of scan data in a second mode.

FIG. 9 is a diagram showing an example of a liquid crystal applied voltage waveform used in the liquid crystal display device of the second embodiment.

FIG. 10 is a diagram showing an example of a liquid crystal applied voltage waveform used in the liquid crystal display device of the third embodiment.

FIG. 11 is a diagram showing a liquid crystal drive voltage generating circuit used in the liquid crystal display device of the fourth embodiment.

FIG. 12 is a diagram showing a liquid crystal drive voltage generation circuit used in the liquid crystal display device of the fifth embodiment.

FIG. 13 is a diagram showing a liquid crystal drive voltage generation circuit used in the liquid crystal display device of the sixth embodiment.

FIG. 14 is a main-portion circuit diagram of a first liquid crystal display device of a sixth embodiment.

FIG. 15 is a circuit diagram of an essential part of a second liquid crystal display device according to a sixth embodiment.

16 is a circuit diagram of an example of a signal generation circuit in FIG.

17 is a circuit diagram of an example of a signal generation circuit in FIG.

[Explanation of symbols]

 101 liquid crystal display element 102 scanning driver circuit 103 signal driver circuit 104 liquid crystal module 105 scanning electrode 106 signal electrode 107 liquid crystal drive voltage generating circuit 201 data generating circuit 202 TV tuner / video input circuit 203 ADC circuit 204 microprocessor 205 mode switching circuit 206 image Signal data generation circuit 207 Scan data generation circuit 208 Mode switching timing generation circuit

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Seiichi Sagi 8th Shinsugita-cho, Isogo-ku, Yokohama-shi, Kanagawa Incorporated company Toshiba Yokohama Office

Claims (7)

[Claims] 1. A plurality of scan electrodes running in a first direction, to which either a scan voltage or a non-scan voltage is applied by switching, and a second scan electrode orthogonal to the first direction. Liquid crystal sandwiched between the scanning electrodes and the signal electrodes, and a plurality of signal electrodes that run in the direction of, in which either a selection signal voltage or a non-selection signal voltage is applied by switching. Mode switching means for switching between a layer, a first mode for displaying an image with pixels of two gradations, and a second mode for displaying an image with pixels of three or more gradations; Scanning voltage applying means for switchably applying the scanning voltage and the non-scanning voltage to the electrodes, the first voltage
In the second mode, the scan voltage is sequentially applied to each one of the plurality of scan electrodes only for the first period, and in the second mode, the scan voltage is M times as long as the second period. Only, scanning voltage applying means for simultaneously applying to each of the M scanning electrodes of the plurality of scanning electrodes and sequentially performing this operation, and driving for selectively switching the selection signal voltage and the non-selection signal voltage to each signal electrode. Voltage applying means, in the first mode, applying a signal of either the selection signal voltage or the non-selection signal voltage to each of the signal electrodes only during the first period, and in the second mode During the second period, one of the two signals of the selection signal voltage and the non-selection signal voltage is selected for each of the signal electrodes for each of the first periods, which is convenient for M times. Signal voltage applying means A liquid crystal display device comprising: 2. The scan electrode applying means selects the M lines of the plurality of scan electrodes to apply the scan voltage, first of all, in the first period of the second period. The M scan electrodes are selected, and then the second M scan electrodes are selected for the second second period that does not overlap with the first second period. 2. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is configured to select and sequentially repeat such non-overlapping selection operations to apply the scanning voltage to the M scanning electrodes in each selection. 3. The scan electrode applying means selects first M of the plurality of scan electrodes and applies the scan voltage, first of all, in the first period of the second period. Only M second scan electrodes are selected, and then only the second second period, which is partially overlapped with the first second period, starts in the middle of the first second period. The second M scanning electrodes are selected, the partially overlapping selection operation is sequentially repeated, and the scanning voltage is applied to each of the M scanning electrodes being selected. The liquid crystal display device according to claim 1, which is provided. 4. The liquid crystal display device according to claim 1, wherein a voltage amplitude (wave) of a difference between the scanning voltage and the first signal voltage when the second mode is selected. The maximum amplitude of the high value is smaller than the voltage amplitude of the difference between the scanning voltage and the selection signal voltage when the first mode is selected, and the multi-gradation pixel in the second mode is set. A liquid crystal display device characterized by displaying an image on the screen. 5. The liquid crystal display device according to claim 1, wherein the voltage amplitude A of the scanning voltage and the voltage amplitude B of the signal voltage are used when the second mode is selected. The bias ratio {B / (A + B)} is set to the first and second 2
Change with the switching of modes between the two modes,
A liquid crystal display device, wherein a bias ratio when the second mode is selected is set to be smaller than a bias ratio when the first mode is selected. 6. The liquid crystal display device according to claim 1, wherein the voltage amplitude A of the scanning voltage and the voltage amplitude B of the signal voltage are used when the second mode is selected. The bias ratio {B / (A + B)} is set to the first and second 2
Change with the switching of modes between the two modes,
When the total number of the scanning electrodes is L, the bias ratio when the first mode is selected is 1 / (L ^1/2 +
1) is set to the center, and the bias ratio when the second mode is selected is 1 / {(L / M) ^1/2 +
1} is set to a value centered on the liquid crystal display device. 7. The display area according to claim 1, wherein each of the display areas performs screen display in any one of the first mode and the second mode. Liquid crystal display device.