JP2001296838A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new active matrix type liquid crystal display device which is able to display high quality animation and has a high energy efficiency. SOLUTION: In the active matrix liquid crystal display device, one frame period is divided into plural sub-frames, the pixels of all the lines to be scanned during the sub-frame period are selected in batch before each sub-frame period, and an elimination signal to uniformalize pixel potentials is written in the pixels selected in batch in synchronization with the batch selection. Since pixel information in the preceding frame is eliminated and each pixel potential is uniformalized before a pixel signal is written, it is possible to eliminate a difference in a liquid crystal response time caused by the difference in the display gradation of the preceding frame by making the initial state of the liquid crystal uniform. Moreover, since the elimination signal is written in batch in the pixels of all the lines to be scanned during the sub-frame period, it is possible to operate with a driving frequency equivalent to a conventional one. Therefore, it is possible to improve picture quality of animation without increasing power consumption of the liquid crystal device.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active matrix type liquid crystal display device, and more particularly to an active matrix type liquid crystal display device capable of displaying a high-quality moving image and consuming less power.

[0002]

2. Description of the Related Art In recent years, liquid crystal display devices (hereinafter, LCDs) capable of realizing high definition, low power consumption and space saving are rapidly spreading in various applications such as computer monitors and television display devices. However, LCD is a cathode ray tube (hereinafter referred to as CR) which has been mainly used for these purposes.
In contrast to T), the image quality in displaying moving images is not sufficient.

For example, as shown in FIG. 9 (a), when displaying a screen in which a white object 50 moves in a certain direction on a black background, the LCD displays an object as shown in FIG. 9 (b). The “motion blur” in which 50 outlines are blurred, and FIG.
As shown in (c), a “ghost” occurs in which the afterimage 51 of the object before movement is perceived.

One of the problems in displaying moving images is that
This is because the response time of the liquid crystal to a signal is long. In a twisted nematic type (TN type) or a super swissed nematic type (STN type) LCD generally used at present, the arrangement of liquid crystal molecules changes after an electric field is applied to the liquid crystal. Since the electro-optical response time required to reach a desired light transmittance is several times longer than 16.7 msec which is a frame period of a general video signal, the optical response of the moving part is not completed within one frame period. For this reason, the delay of the optical response of the liquid crystal is visually recognized as “motion blur” or “ghost”.

[0005] Further, it is also said that the LCD is of a hold type that emits light until it is rewritten with image information of the next frame, which is a cause of poor display quality for moving images. In a thin film transistor type (hereinafter, TFT type) LCD, which is widely used as an LCD, charges accumulated by applying an electric field to the liquid crystal are held at a relatively high rate until the next electric field is applied. For this reason, FIG.
As shown in (1), each pixel of the LCD continues to emit light until it is rewritten by applying an electric field based on the image information of the next frame. On the other hand, in a CRT display device which performs display by emitting light from a phosphor by scanning an electron beam, as shown in FIG. 10B, light emission from each pixel is substantially in an impulse shape.
Therefore, the LCD has a lower time-frequency characteristic of image display light than a CRT, and accordingly, a spatial frequency characteristic is also reduced, resulting in blurring of a viewed image.

Japanese Patent Application Laid-Open No. 11-202286 discloses that a backlight is divided and driven in order to improve image quality in displaying moving images on an LCD. FIG. 11 is a block diagram showing the device configuration. The backlight 54 arranged on the back of the liquid crystal panel is divided into a plurality of light emitting areas 54a to 54d, and each light emitting area 54a is provided with a certain time delay for an image writing operation of the liquid crystal panel in a corresponding area. Discharge lamp 5 located at ~ 54d
6 are sequentially emitted by the lighting control circuit 60.

FIG. 12 is a timing chart showing the relationship between the optical response of the liquid crystal and the light emission timing of the backlight in such a liquid crystal display device. A gate pulse 62 for controlling the timing of writing a video signal to each pixel rises every frame period, and the image information of each pixel is rewritten in synchronization with the rise. The luminance of the liquid crystal optical response 64a of the pixel rewritten from the black image to the white image at the time S1 greatly increases in a frame period immediately after the rewriting, and complete white display takes several frames thereafter. The backlight starts lighting at time S2 when a certain delay time elapses with respect to the rise of the gate pulse 62, and turns off at time S3 when the next gate pulse 62 rises. As a result, the progress of the change in the liquid crystal optical response is hardly seen by the observer, and the light emission of each pixel becomes close to an impulse, so that the image quality in moving image display is improved.

In addition, instead of a TN type LCD having a slow response speed, a pi-cell type L-type LCD which can respond in a few msec.
The optical response is enhanced by using a CD,
It has been proposed to improve the image quality of moving image display by performing a cyclic resetting driving method (hereinafter, referred to as a CR driving method) in which writing is performed twice during a frame so as to approximate an impulse type light emission.

FIG. 13 is a timing chart showing operation timing in such a liquid crystal display device. The gate pulse 64 rises twice during one frame period, the image signal is written at the first rising, and the black signal is written at the second rising. For example, when the black image is rewritten from the black image to the white image at the time S1 ′, the liquid crystal optical response 66 changes to the white display in a short time after the rewriting, the white display is continued in the first half of the frame period, and the frame intermediate time S2 'Is changed to black display, and black display is performed in the latter half of the frame period. Since the liquid crystal responds in a short time and displays an image in the first half of the frame and performs black display in the second half of the frame, the light emission state of each pixel approaches an impulse type, thereby improving the image quality in moving image display.

[0010]

However, the above-mentioned conventional liquid crystal display device has the following problems. First, in the case of a liquid crystal display device in which a backlight is divided and driven as described in Japanese Patent Application Laid-Open No. 11-202286, of the above-described problems in displaying moving images, “moving image blur” is improved, but “ "Ghost" cannot be eliminated enough. FIG.
As shown in (c), the cause of the ghost is that the contrast difference based on the difference in the liquid crystal response time between the region 52 where the black image is rewritten into the white image and the region 53 where the white image is rewritten with the white image. Is to happen. However, since the response time of the TN type liquid crystal is several times longer than the frame period, as shown in FIG. 12, a liquid crystal optical response 64a corresponding to the area 52 where the black image is rewritten to the white image, and
There is a luminance difference between the white image and the liquid crystal optical response 64b corresponding to the area 53 rewritten to the white image even during the period in which the backlight is turned on (S2 to S3). The luminance difference completely disappears several frames after rewriting. Therefore, no matter how much the lighting time of the backlight is limited, a ghost remains.

On the other hand, a Pi-cell type LC using the CR driving method
In the case of D, since the response speed of the liquid crystal is high, it is possible to take measures against both “moving image blur” and “ghost”. However, as a result of performing the CR driving method, there is a problem that the power consumption of the liquid crystal display device increases, and the energy efficiency represented by the ratio of the power consumption to the screen luminance is deteriorated. The power consumption of the liquid crystal display device can be divided into the power consumption of the liquid crystal panel and the power consumption of the backlight. However, both of them are increased in the CR driving method.

First, as shown in FIG. 13, in the CR driving method, the writing frequency is doubled because writing is performed twice during one frame period, but the power consumption of the liquid crystal panel is almost equal to the driving frequency. Because of the proportionality, the power consumption of the liquid crystal panel is about twice that of the conventional case. Further, as shown in FIG. 13, in the CR driving method, the backlight is continuously lit, and the liquid crystal panel itself is displayed in black by performing impulse-type light emission. Therefore, about half of the power consumption of the backlight is reduced. It is wasted regardless of screen brightness. Therefore, in order to secure the same brightness as the conventional one, the power supply to the backlight must be doubled, and the power consumption is about twice that of the conventional one. In addition to the problem of energy efficiency, the manufacturing of a pi-cell type LCD requires a different manufacturing technology from that of a conventionally used TN type LCD. There was also a problem that it was needed.

It is an object of the present invention to provide a new active matrix type liquid crystal display device capable of displaying a high-quality moving image and having high energy efficiency.

[0014]

In order to achieve the above object, a liquid crystal display device according to the present invention comprises: an image display section having pixels arranged in a matrix and switch means connected to each pixel; A row driving circuit for selecting one pixel for each line while scanning and scanning one screen over one frame period, and a column for writing an image signal to a pixel of the selected line in synchronization with the scanning In the liquid crystal display device including a driving circuit, the row driving circuit divides one frame period into a plurality of sub-frame periods, and before each sub-frame period, scans pixels of all lines scanned during the sub-frame period. Batch selection is performed, and in synchronization with the batch selection, the column drive circuit writes an erasure signal for aligning pixel potentials to the pixels that are collectively selected.

Before the image signal is written, the image information of the previous frame is erased to equalize the pixel potentials, so that the initial state of the liquid crystal is made uniform and the difference in the liquid crystal response time due to the difference in the display gradation of the previous frame is eliminated. can do. In addition, since the erase signal is collectively written to the pixels of all the lines scanned during the sub-frame period, it is possible to operate at the same driving frequency as the conventional one. Therefore, excellent moving image quality without "ghost" can be achieved without increasing the power consumption of the liquid crystal display device.

It is preferable that the erase signal for adjusting the pixel potential has a voltage level higher than the maximum voltage level of the image signal. In general, a liquid crystal display element has a higher response speed when the applied voltage is turned off from the applied voltage is turned on than when the applied voltage is turned on.
This is because the response speed increases.

Further, in order to prevent image sticking due to impurities in the liquid crystal, it is preferable to invert the polarity of the erase signal for each frame.

Still further, the row drive circuit may perform the batch selection for the n-th (n is an integer) sub-frame period simultaneously with the selection of one line in the (n-1) -th sub-frame period. preferable. This allows
Since there is no need to set a new timing different from the conventional one, it becomes possible to write the erase signal without making the conventional driving circuit so complicated.

However, in this case, since the erase signal is written in place of the image signal on the line on which the batch selection is performed at the same time, there is a problem that a horizontal line appears on the screen. Therefore, it is preferable to re-select a line on which batch selection is performed at the same time as at least one line after the line. This makes it possible to write an image signal close to the originally written information to the pixel to which the erase signal has been written, and to make the horizontal line inconspicuous.

In addition, in order to make the horizontal lines more difficult to see, the lines that are selected simultaneously may be different lines for each frame.

The batch selection for the n-th sub-frame period may be performed in place of the selection of one line in the (n-1) -th sub-frame period, and the line may be different for each frame.

Further, a light source capable of illuminating each divided display area composed of pixel rows scanned in each sub-frame period is provided on a back surface of the image display section, and the light source divides each divided display area into a corresponding one of the divided display areas. It is preferable to illuminate for a predetermined period after the end of scanning. Thereby, the light emission of the liquid crystal display device can be of an impulse type, and excellent moving image quality without “ghost” and “moving image blur” can be obtained.

It is preferable that the light source does not illuminate each divided display area while an erase signal is written in the divided display area. Thereby, the disturbance of the image during the erasure of the image is not visible to the viewer, and it is possible to prevent the occurrence of a chromaticity shift or the like.

Further, the liquid crystal display device of the present invention can display a high-quality moving image even when using a liquid crystal having a low response speed, and thus can be of a twisted nematic type. Therefore, it can be easily manufactured utilizing the conventional manufacturing technology.

The present invention is also a liquid crystal monitor provided with the liquid crystal display according to the present invention. Since the liquid crystal display device according to the present invention has the same energy efficiency as the conventional one and is capable of displaying a high-quality moving image, it is suitable for portable use and is suitable for moving images by forming a liquid crystal monitor using the same. An excellent liquid crystal monitor can be provided.

Further, the present invention is also a personal computer provided with such a liquid crystal monitor. A personal computer that can display high-quality moving images and is suitable for multimedia applications can be provided.

[0027]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 is a schematic diagram showing a liquid crystal display device according to Embodiment 1 of the present invention.
The liquid crystal display device 20 includes a liquid crystal panel 22, a vertical drive circuit (= row drive circuit) 24, and a horizontal drive circuit (= column drive circuit).
30 and a backlight on the back of the liquid crystal panel. In the image display unit 22a of the liquid crystal panel 22, pixels are arranged in a matrix, and a switching element such as a thin film transistor (hereinafter, referred to as a TFT) is connected to each pixel. In FIG. 1, pixels and TFTs are omitted. The vertical drive circuit 24 is a gate driver I driven based on a timing signal sent from the control circuit 33.
C26 is provided on the vertical circuit board 25, and one screen is scanned over one frame period while driving the TFT of each pixel line by line via the gate wiring 28. Also,
The horizontal drive circuit 30 receives a timing signal and an image signal from the control circuit 33 and drives the source driver IC.
On the horizontal circuit board 31 and the source signal lines 34
, An image signal is written to the pixel row selected by the vertical drive circuit 24.

The image display section 22a is divided into, for example, eight divided display areas (# 1 to # 8), and the vertical drive circuit 24 controls all of the divided display areas before scanning the divided display areas. And the horizontal drive circuit 30 writes an erasure signal to each pixel in synchronization with the batch selection.
This makes it possible to erase the image information of the previous frame before writing the image signal, and to make the optical response time of each pixel uniform regardless of the display image of the previous frame. Further, the number of selections of the gate wiring for writing the batch erase signal is eight times in one frame, which is smaller than the number of selections of the gate wiring for writing the image signal (usually 480 to 800 times). The erase signal can be written while the gate line driving frequency remains the same as in the conventional case.

FIGS. 2 and 3 are a side view and a rear view showing the liquid crystal display device shown in FIG. In the backlight 36 installed on the back of the liquid crystal panel 22, the image display unit 2 is provided.
Eight cold cathode fluorescent tubes 38 are arranged corresponding to each of the divided display areas # 1 to # 8 of 2a, and a light-shielding wall 40 is provided at a boundary between the respective lighting areas. Backlight 36
The eight cold cathode fluorescent tubes 38 are driven by a backlight lighting circuit 42. Backlight lighting circuit 42
Turns on each cold-cathode tube 38 after a certain delay time in synchronization with the scanning of each divided display area by the vertical drive circuit 24, based on a control signal from the control circuit 33. Thereby, the light emission of the liquid crystal display device can be made to be in a state approximate to an impulse type.

Hereinafter, the operation of the liquid crystal display device will be described in detail. The basic operation is a line-sequential image drawing method, in which the gate lines 28 are sequentially selected in synchronization with a synchronizing signal in a video signal, and each liquid crystal pixel connected to the gate line 28 The gray scale voltage to be assigned as the source signal is supplied from the source signal line 34. As shown in FIG. 8, the transmittance of the liquid crystal panel changes in accordance with the written grayscale voltage, so that the video signal can be converted into an optical signal by changing the light from the backlight. An image is displayed by repeating this operation while sequentially selecting the gate lines 28.

FIG. 4 is a block diagram showing a driving circuit of the liquid crystal display device shown in FIG. The driving circuit includes the image display unit 2
2a, a vertical drive circuit 24, a horizontal drive circuit 30, and a backlight control circuit 18, which operate based on an externally input image signal and synchronization signal. Image display unit 2
2a is divided into eight divided display areas # 1 to # 8, and each divided display area has a matrix arrangement of liquid crystal pixels 1 and TFT elements 2 connected thereto. Each T
The liquid crystal pixel 1 is connected to the drain of the FT element 2, and each TFT
A gate line 28 is commonly connected to the gate of the element 2 for each row, and a source signal line 34 is commonly connected to the source of each TFT element 2 for each column.

The vertical drive circuit 24 has a vertical driver control circuit 17, a shift register 12, and an output buffer 14, as in a general active matrix liquid crystal display device, and connects a gate line 28 of the image display section 22a to a line. Scan and drive sequentially. However, unlike a general liquid crystal display device, an OR circuit 13 is provided between the shift register 12 and the output buffer 14, and an output signal of the shift register is input to one of the input sides of the OR circuit 13. The batch selection signals BW1 to BW8 are input to the other of the sides. The batch selection signal input side of the OR circuit 13 is connected to each of the corresponding divided display areas, and the batch selection signal BW1 corresponding to the number # 1 to # 8 of each divided display area.
To BW8 are input. When the collective selection signals BW1 to BW8 are input, all the TFTs in the divided display area
The elements 2 are turned on at once.

The horizontal drive circuit 30 has a horizontal driver control circuit 16, a shift register 6, a latch circuit 7, a D / A converter 8, and an inverter 9 as in a general active matrix liquid crystal display device. In synchronization with the drive circuit 24, an image signal is written to a pixel in a row selected by the vertical drive circuit 24. However, unlike a general liquid crystal display device, the horizontal driving circuit 30 combines the erasing signal with the image signal in the image signal processing circuit 4 so that the erasing signal is synchronized with the batch selection timing by the vertical driving circuit 24. Write.

The backlight control circuit 18 synchronizes with the selection of the gate wiring by the vertical drive circuit 24, and after a fixed delay time from the end of scanning of each of the divided display areas # 1 to # 8, Is turned on for a predetermined time.

FIG. 5 is a timing chart showing the optical response of each pixel row and the lighting timing of the backlight in the divided display areas # 1 to # 8. In FIG. 5, each curve represents the optical response waveform of the liquid crystal in each pixel row, and the hatched portion represents the lighting period of the backlight. Vertical drive circuit 24
Divides _one frame period into eight sub-frame periods (t _{1 to} t ₈ ) except for a blanking period, and during each sub-frame period, the corresponding divided display area # 1 to # 8 A write scan is performed. For example, if the frame frequency is 6
At 0 Hz, one frame period is 16.6 msec, and excluding the blanking period, about 2/8 of 16/8
At ec, a writing scan is performed in each divided display area.

A description will be given focusing on the divided display area # 1. First, the last sub-frame period t ₈ ′ of a certain frame period
, The vertical drive circuit 24 causes the divided display area # 1
, All the pixel rows are collectively selected, and in synchronization with this, the horizontal driving circuit 30 outputs an erasing signal V equal to or higher than the maximum gradation (black gradation) of the liquid crystal.
_h is applied and the potentials of the pixels in the divided display area # 1 are aligned. Subsequently, in the first sub-frame period t ₁ of the next frame period, each pixel row of the divided display area # 1 is sequentially scanned by the vertical drive circuit 24, and in synchronization with this, the horizontal drive circuit 30 outputs an image to each pixel. The signal is written. Then, 8m corresponding to the sub-frame period t ₂ ~t ₅
After a sec delay time, the sub-frame period t ₆ and t _7, the backlight of the region corresponding to the divided display area # 1 by the backlight drive circuit 18 is turned on. In the final subframe period t _8, the backlight is turned off, the erase signal V _h is applied all the pixel rows in the divided display area # 1 is collectively selected again.

In the divided display areas # 2 to # 8, the same operation as in the divided display area # 1 is performed while shifting the timing by one subframe period (2 msec). For example, in the sub-frame period t ₈ ′, the divided display area 1 is collectively selected, the divided display area 8 is scanned, and the backlights of the divided display areas 2 and 3 are turned on. In subframe periods t ₁ is divided display area 1 is scanned, the divided display region 2 is simultaneously selected, the backlight of the divided display areas 3 and 4 are on.

[0038] Thus in a liquid crystal display device which is driven, the potential of all the pixels in the divided display area before writing of the image signal is aligned with the V _h, also, the liquid crystal response after writing of the image signal is somewhat stable Since the backlight is turned on only during the period, even if the pixels have different display gradations in the previous frame period, a shift in the liquid crystal optical response is hardly perceived. Therefore, even when a liquid crystal having a low response speed such as a TN type liquid crystal is used, the ghost can be almost completely eliminated. Also, since the lighting period of the backlight is limited, an impulse-type light emission state is obtained.
A sharp image without "motion blur" can be obtained.

Further, since the backlight is turned off while the pixel potential is _adjusted to Vh and the image in the previous frame period is erased, the shift of the optical response between pixels during this image erasing period is invisible to the user. Also, the problem of chromaticity shift does not occur.

[0040] Incidentally, from the viewpoint of erasing the "ghost" is preferably erase signal is black signal, the voltage V _h is as high as possible are preferable. In the case of a general normally white driving TN type liquid crystal display device, the response speed of the liquid crystal is faster when changing from white gradation to black gradation, and the response is generally higher when the applied voltage is higher. This is because the speed increases. Further, as the burn-measures by impurities in the liquid crystal, each display region the polarity of V _h, or causes it is preferable that inverted every frame.

In this embodiment, the backlight lighting time of each divided display area is about 4 msec, and the backlight lighting time ratio is about 1/4. Therefore, in order to secure the same screen brightness as in the conventional case where the backlight is continuously turned on, the emission brightness of the backlight is increased about four times by increasing the number of cold cathode tubes in the backlight or the like. There is a need. However, since the power consumption is reduced to 1/4 of the conventional one in proportion to the lighting time ratio of the backlight, the power consumption can be made equal to the conventional one even if the luminance of the backlight is increased.

The backlight lighting time ratio can be adjusted by changing the above-mentioned delay time, and may be appropriately set in consideration of the balance between moving image display and screen luminance. From the viewpoint of displaying moving images, it is preferable to set the lighting time ratio small so that light is emitted after the optical response of the liquid crystal is stabilized, while it is preferable to set the lighting time ratio large from the viewpoint of screen luminance.

Next, the specific timing of writing the erase signal, writing the image signal, and turning on the backlight will be described with reference to FIG. FIG. 6 shows the timing from the sub-frame period t ₈ ′ to t _2. The upper part of the figure shows the potential of the source signal line, and the middle part shows the first to fourth rows in the divided display areas # 1 and # 2. The lower row shows the lighting timing of the backlight in the divided display areas # 1 to # 4.

First, in the subframe period t ₈ ′,
At the first timing determined by the synchronization signal of the image signal, the backlight of the area corresponding to the divided display area # 1 is turned off, the backlight of the area corresponding to the divided display area # 3 is turned on, and the divided display area # All of the 1 gate lines are collectively selected and the erase signal _Vh is supplied from the source signal line.
Subsequently, over the remaining period of the sub-frame period t ₈ ′, the gate wiring of the divided display region # 8 is sequentially selected, and the image signal V _sig to be assigned to each pixel is supplied from the source signal line. Then, the sub-frame period t _1,
At the first timing, the backlight of the area corresponding to the divided display area # 2 is turned off, the backlight of the area corresponding to the divided display area # 4 is turned on, and all the gate wirings of the divided display area # 2 are collectively selected. An erase signal _Vh is supplied from a source signal line. Then, over the remainder of the sub-frame periods t _1, all gate lines of the divided display region # 1 is the image signal V _sig is supplied to be assigned to each pixel is sequentially selected. The same operation is repeated in the subsequent subframe periods.

As shown in FIG. 6, the batch selection of the n-th divided display area is performed simultaneously with the selection of the first row of the (n-1) -th divided display area. The erase signal _Vh is output. By performing such driving, the collective erasing signal can be written at the same driving frequency as in the case of performing normal image writing, and the power consumption of the liquid crystal panel can be made equal to that in the related art. However, this is the pixel of the first row of the divided display areas will be canceled signal V _h in place of the image signal V _sig is written, a problem that the first row of the divided display area is visible in a black horizontal line Occurs.

Therefore, in the present embodiment, FIG.
As described above, the erase signal V is applied to the pixels in the first row of each divided display area.
_hIs written, the pixels in the first row of each divided display area
Is re-selected simultaneously with the selection of the pixels in the second row,
The image signal V of the second row is applied to both the pixels of the second row._sigWrite
No. When selecting the third and subsequent gate lines,
Similarly, simply correspond to the pixel connected to the gate line.
Image signal V_sigIs repeated. This
The erase signal V_hImmediately after is written
And the image signal V that should be given_sigGive a signal close to
Can solve the problem of black horizontal lines.
it can. Incidentally, as shown in FIG. _sigThe pixel row
When the polarity is inverted every time, the polarity is the same as the original polarity.
To give an image signal, the image on the first line of each divided display area
The element may be reselected simultaneously with the selection of the pixel in the third row.

In the present embodiment, an example will be described in which writing of an erase signal to the n-th divided display area is performed simultaneously with selection of the first row of the (n-1) -th divided display area. However, the present invention is not limited to the case where the selection is performed simultaneously with the selection of the first row. If the row is located at about 1/4 of the scanning start side of the (n-1) th divided display area, the row (hereinafter, referred to as the row)
At the same time as the i-th row (i is an integer), the erasure signal can be written to the n-th divided display area. Further, in this case, the occurrence of a black horizontal line can be prevented by reselecting the pixel in the i-th row at the same time as the pixel in the (i + 1) -th row or the (i + 2) -th row.

Embodiment 2 In the first embodiment,
In order to solve the problem of the occurrence of the black horizontal line, the pixel row in which the erasure signal is written is reselected simultaneously with the next pixel row or the next pixel row. In the present embodiment, the horizontal lines are made inconspicuous by changing the timing of writing the erase signal randomly or periodically.

For example, as shown in FIG. 7A, the timing at which the n-th divided display area is collectively selected is set to (n-
1) Periodically change in the range of the first to fifth rows in the first divided display area. As a result, it is possible to make it difficult for a viewer to perceive the existence of the horizontal line by changing the line where the black horizontal line occurs in each frame. The range in which the timing of performing the batch selection is changed may be extended to about 1/4 of the scanning start side of the (n-1) th divided display area, and the timing may be changed at random.

Further, as shown in FIG. 7A, while changing the timing of the erasing signal, the pixels in the row where the erasing signal is written are moved to the next or one pixel in the same manner as in the first embodiment.
A row may be selected again at the same time as the next row of pixels. As a result, the horizontal lines are no longer black, and the horizontal lines can be made less noticeable.

In addition to the operation shown in FIG. 7 (a), as shown in FIG. 7 (b), the n-th divided display area is simultaneously selected in the (n-1) -th pixel row. The selection may not be performed. When such an operation is performed, the image data of the previous frame remains without rewriting the image signal in the pixel row in which the collective selection is performed at the same time. However, the timing at which the collective selection is performed at the same time changes. Image signals are written in the frame. Therefore, a row displaying the same image information continuously for two frames appears on the screen while periodically changing the location. Thereby, the influence on the screen due to the writing of the erase signal can be further suppressed.

Embodiment 3 FIG. The liquid crystal display device described in Embodiment 1 or 2 can be housed in a housing together with a power supply for driving the liquid crystal display device, an input terminal for a video signal, and the like, to form a liquid crystal monitor. The thus configured liquid crystal monitor can display high-quality moving images with low power consumption. In addition, a personal computer can be configured by combining a storage device and an arithmetic device with the liquid crystal monitor. The personal computer thus configured is excellent in displaying moving images and suitable for multimedia applications.

[0053]

The present invention has the following effects because it is configured as described above. In the liquid crystal display device of the present invention, before each sub-frame period, pixels on all lines to be scanned during the sub-frame period are collectively selected, and an erasing signal for aligning pixel potentials is written in synchronization with the collective selection. Therefore, the initial state of the liquid crystal can be made uniform, and the difference in the liquid crystal response time due to the difference in the display gradation of the previous frame can be eliminated. In addition, since the erase signal is collectively written to the pixels of all the lines scanned during the sub-frame period, it is possible to operate at the same driving frequency as the conventional one. Therefore, "ghost" can be improved and the image quality of moving image display can be improved without increasing the power consumption of the liquid crystal display device.

Further, since the erase signal has a voltage level equal to or higher than the maximum voltage level of the image signal, the initial state of the liquid crystal can be quickly uniformed, and the image quality of a moving image can be further improved.

Further, by inverting the polarity of the erase signal for each frame, it is possible to prevent burn-in due to impurities in the liquid crystal.

Furthermore, by simultaneously selecting one line in the (n-1) th subframe period, the batch selection for the nth subframe period is performed.
Since there is no need to set a new timing different from the conventional one, it becomes possible to write the erase signal without making the conventional driving circuit so complicated.

In addition, the lines for performing the batch selection at the same time are:
By reselecting at the same time as at least one line after the line, an image signal close to information to be originally written is written to the pixel to which the erase signal has been written,
A horizontal line generated by writing the erase signal can be prevented from being recognized by a viewer.

In addition, by making the lines on which the batch selection is performed at the same time different for each frame, it is possible to make it more difficult to recognize horizontal lines.

The batch selection for the n-th sub-frame period is performed in place of the selection of one line in the (n-1) -th sub-frame period, and the line is set to a different line for each frame. Also, the horizontal line can be prevented from being recognized by the viewer.

Further, a light source which can be illuminated for each divided display area is provided on the back surface of the image display section, and each divided display area is illuminated for a predetermined period with a delay from the end of scanning of the area, thereby providing a liquid crystal display device. The image quality of moving image display can be further improved by making the light emission an impulse type.

Further, since each divided display area is not illuminated while an erasure signal is written in the divided display area, the disturbance of the image during the erasure of the image is prevented from being recognized by the viewer, and the chromaticity is reduced. The occurrence of displacement or the like can be prevented.

Further, by making the liquid crystal display device of the present invention a twisted nematic type, it can be easily manufactured utilizing the conventional manufacturing technology.

Further, by configuring a liquid crystal monitor using the liquid crystal display device according to the present invention, it is possible to provide a liquid crystal monitor which is suitable for portable use and excellent in handling moving images.

Further, according to the present invention, by configuring a personal computer using such a liquid crystal monitor, a high-quality moving image can be displayed and a personal computer suitable for multimedia use can be provided.

[Brief description of the drawings]

FIG. 1 is a front view showing a liquid crystal display device according to Embodiment 1 of the present invention.

FIG. 2 is a side view showing the liquid crystal display device according to Embodiment 1 of the present invention.

FIG. 3 is a rear view showing the liquid crystal display device according to Embodiment 1 of the present invention.

FIG. 4 is a block diagram showing a driving circuit of the liquid crystal display device according to Embodiment 1 of the present invention.

FIG. 5 is a timing chart showing a liquid crystal optical response and a backlight lighting timing in the liquid crystal display device according to the first embodiment of the present invention.

FIG. 6 is a timing chart showing a change in potential between a source signal line and a gate line and timing of lighting of a backlight in the liquid crystal display device according to the first embodiment of the present invention.

FIGS. 7A and 7B are schematic diagrams showing a potential change of a gate wiring in a liquid crystal display device according to a second embodiment of the present invention.

FIG. 8 is a graph showing a relationship between a writing voltage of a liquid crystal panel and a transmitted light intensity.

FIGS. 9A to 9C are schematic diagrams showing abnormal image quality in moving image display.

FIGS. 10A and 10B show TFT-LC.
It is a schematic diagram which shows the light emission signal of D and CRT.

FIG. 11 is a schematic diagram showing a configuration of a conventional liquid crystal display device.

FIG. 12 is a timing chart showing an operation of the conventional liquid crystal display device.

FIG. 13 is a timing chart showing an operation of another example of the conventional liquid crystal display device.

[Explanation of symbols]

1 pixel, 2 TFTs, 4 image signal processing circuits, 6 horizontal shift registers, 7 latch circuits, 8 D / A converters, 9 and 14 buffers, 12 vertical shift registers, 13 OR circuits, 16 horizontal driver circuits, 17
Vertical driver circuit, 18 backlight control circuit, 20
Liquid crystal display device, 22 liquid crystal panel, 22a image display unit, 24 vertical drive circuit, 25 vertical circuit board, 26
Gate driver IC, 28 gate wiring, 30 horizontal drive circuit, 31 horizontal circuit board, 32 source driver I
C, 33 driver control circuit, 34 source signal line, 3
6 backlight, 38 cold cathode tube, 40 light shielding wall, 42
Backlight lighting circuit.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 641 G09G 3/20 641E 660 660V (72) Inventor Junichi Fujino 2-1-2 Marunouchi, Chiyoda-ku, Tokyo No. 3 Mitsubishi Electric Co., Ltd. (72) Kyoichiro Oda, inventor 2-3-2 Marunouchi, Chiyoda-ku, Tokyo Mitsui Electric Co., Ltd. (72) Inventor Toshio Tobita 2-3-2, Marunouchi, Chiyoda-ku, Tokyo No. Mitsubishi Electric Corporation F-term (reference) 2H093 NA16 NA31 NA41 NC22 NC26 NC42 ND01 ND12 ND39 NF05 NF13 5C006 AA14 AC21 AC28 BB16 EA01 FA29 FA47 5C080 AA10 BB05 DD01 DD26 EE19 EE19 EE29 FF11 JJ01 JJ04 JJ04 KK04 JJ04 JJ04 KK04

Claims (12)

[Claims] 1. An image display unit having pixels arranged in a matrix and switch means connected to each pixel, and selecting the pixels for each line while driving the switch means, for one frame period. A liquid crystal display device comprising: a row driving circuit for scanning one screen; and a column driving circuit for writing an image signal to a pixel on a selected line in synchronization with the scanning. The period is divided into a plurality of sub-frame periods, and before each sub-frame period, pixels of all lines to be scanned during the sub-frame period are collectively selected.
A liquid crystal display device, wherein the column drive circuit writes an erasure signal for aligning pixel potentials to pixels selected in a batch in synchronization with the batch selection. 2. The liquid crystal display device according to claim 1, wherein the erase signal has a voltage level higher than a maximum voltage level of the image signal. 3. The liquid crystal display device according to claim 1, wherein the erase signal inverts the polarity every frame. 4. An n-th row drive circuit (where n is an integer).
(N-1)
2. The liquid crystal display device according to claim 1, wherein the operation is performed at the same time as the selection of one line in the sub-frame period. 5. The liquid crystal display device according to claim 4, wherein the row drive circuit reselects one line on which the batch selection is performed at the same time as at least one line after the line. 6. The liquid crystal display device according to claim 4, wherein one line in which the row drive circuit performs the batch selection at the same time is a different line for each frame. 7. An n-th row drive circuit (where n is an integer)
(N-1)
2. The liquid crystal display device according to claim 1, wherein the selection is performed in place of the selection of one line in the first sub-frame period, and the one line is a different line for each frame. 8. A light source which is illuminated on a back surface of the image display unit for each divided display area composed of pixel rows scanned in each subframe period, and wherein the light source divides each divided display area into: 2. The liquid crystal display device according to claim 1, wherein the illumination is performed for a predetermined period with a delay from the end of scanning of the area. 9. The liquid crystal display device according to claim 8, wherein the light source does not illuminate each divided display area while an erase signal is written in the divided display area. 10. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is a twisted nematic type. 11. A liquid crystal monitor comprising the liquid crystal display device according to claim 1. 12. A personal computer comprising the liquid crystal monitor according to claim 11.