JP2001343922A - Image display device and its driving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a non-matched image display mode displaying a video image whose aspect ratio is not matched to the aspect ratio of a screen of a display device without lowering image quality and also to reduce power consumption in an image display device in which a preliminary charged potential stabilizing circuit consisting of passive elements is used as a preliminary charged potential stabilizing means in front of a preliminary charging circuit and also to reduce power consumption. SOLUTION: In this display device, a preliminary charged potential stabilizing circuit consisting of passive elements is used as the preliminary charged potential stabilizing means and one part of the display part of the device is set as the non-display area of the video data where the video data are not displayed at the time of the non-matched image display mode and at the time of performing display with fixed luminance by the preliminary charged potential inputted from a preliminary charging circuit in the non-display area of the video data, a scanning signal is stopped for a fixed period.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image display device and a method of driving the same, and more particularly, to driving of an image display device having a non-matched image display mode for displaying a video image having an aspect ratio that does not match the aspect ratio of the screen of the display device. A method and an apparatus therefor.

[0002]

2. Description of the Related Art In recent years, active matrix type liquid crystal display devices have been frequently used in TV (television) monitors, portable information terminals and the like. In many cases, the aspect ratio of the video or image to be displayed does not match the aspect ratio of the screen of the display device. For example, there is a case where a liquid crystal display device mainly for displaying an NTSC TV picture is used to convert a MUSE or other high-definition broadcast to the NTSC format and display it. There is also a case where a liquid crystal display device having an aspect ratio of 16: 9 displays an NTSC system TV image having an aspect ratio of 4: 3.

Generally, when displaying an image or an image having an aspect ratio that does not match the aspect ratio of the screen of the display device (hereinafter referred to as a non-matching image display mode), for example, an aspect ratio of a liquid crystal display device having a screen aspect ratio of 4: 3 is used. Ratio 1
When a 6: 9 video source is displayed, the video displayed by the liquid crystal display device may be displayed in black at the top and bottom of the screen as shown in FIG. 15 or may be cut at the left and right as shown in FIG. Will be. However, in the latter case, in which the height of the video source is displayed according to the height of the screen, it is possible that important information is posted on the cut video. The former, which displays according to the width of the screen, is more widely used. Hereinafter, displaying a video source having an aspect ratio of 16: 9 is referred to as a wide mode, and displaying a video source having an aspect ratio of 4: 3 is referred to as a normal mode.

A liquid crystal display device is often used for a video camcorder and the like, and the display screen in such a case is often of an aspect ratio of 4: 3. However, in recent years, TVs installed in homes are becoming more and more horizontal.
When an image shot by the video camcorder is displayed on a landscape TV, the top and bottom of the image are cut. Therefore, in order to prevent this, when shooting with the video camcorder, as shown in FIG. 15, when displaying on the liquid crystal display device on the video camcorder side in advance, black display is performed vertically, and when displaying on the landscape TV, Techniques for preventing the top and bottom of the screen from being cut are also widely used.

On the other hand, as a method for displaying an image having an aspect ratio of 4: 3 on a display device mainly for displaying a TV image of the high-definition television standard, the entire image is displayed at the center of the screen in a normal mode, and is generated on the left and right of the screen. A method of masking a blank portion with black or an arbitrary color has also been proposed.
For example, Japanese Patent Application Laid-Open No. Hei 7-20816 discloses a group of pixels arranged in a matrix on a horizontally long screen, a group of gate lines connected to each pixel row, a vertical drive circuit connected to the group of gate lines, and each pixel. A data line group connected to the column, a signal line for supplying an image signal from the outside, a sampling switch group for connecting the signal line and the data line group, and a horizontal shift register for controlling the sequential opening and closing operation of the sampling switch group And
The pixel row of the horizontally long screen is divided into a predetermined area for normal display and an extended area for wide mode display, and the horizontal shift register is divided into an extended step portion corresponding to the pixel row of the predetermined area and the extended area. At this time, the predetermined stage portion and the extension stage portion of the horizontal shift register are connected in series to be integrated, and in the normal mode, only the sampling switches belonging to the predetermined region in the sampling switch group are separated by separating the extension stage portion of the horizontal shift register. There has been proposed an active matrix display device in which are sequentially opened and closed. In this display device, in the normal mode, a signal of a constant level is supplied to the data lines belonging to the extended areas at both ends of the screen by the mask means so that the extended area is mask-displayed, and in the wide mode, the entire screen is used. It is.

An active matrix type liquid crystal display device will be described as an example of a conventional image display device that performs black display at the top and bottom of the screen among the above liquid crystal display devices.
As shown in FIG. 11, the image display device includes a pixel array ARY, a scanning signal line driving circuit GD, a data signal line driving circuit SD, a pre-charging circuit PC, and a control signal generating circuit CTL.
It is composed of Further, a current amplifier Buffer is provided at a stage preceding the precharge circuit PC as precharge potential stabilizing means for stabilizing the precharge potential PCV input to the precharge circuit PC.

The pixel array ARY includes a plurality of scanning signal lines GLj (J = 1 to n) and data signal lines SDLi that cross each other.
(i = 1 to m), and two adjacent scanning signal lines G
Pixels PIX are provided in a matrix at a portion surrounded by Lj and the adjacent data signal line SDLi. A display unit including the pixel array ARY includes a scanning signal line GL.
In synchronization with the scanning signal supplied from j, a video signal DAT is written from each data signal line SDLi to each pixel PIX to display an image.

As shown in FIG. 12, the pixel PIX includes a switch element SW, a liquid crystal capacitor CL, and an auxiliary capacitor Cs. The pixel capacitance Cp is equal to the liquid crystal capacitance CL and the auxiliary capacitance C.
It is the sum of s. The data signal line drive circuit SD has a function of sampling the video signal DAT inputted by the analog switch in synchronization with timing signals such as the clock signal CKS and the data start signal SPS, and writing the data signal to each data signal line SDLi as necessary. I do.

The scanning signal line driving circuit GD includes a clock signal CKG, a scanning start signal SPG, and a pulse width control signal P.
In synchronization with a timing signal such as WC, the scanning signal line GLj
Are sequentially selected, and the video signal DAT written to each data signal line SDLi is written to each pixel PIX by opening and closing the switch element SW in the pixel PIX,
The video signal DAT written to the capacitance in each pixel PIX is held.

The pre-charging circuit PC receives a pre-charging control signal P
Precharge potential P input in synchronization with the timing of CC
CV is sampled, and before the video signal DAT is written to each data signal line SDLi, the precharge potential PCV
Works to write. By repeating the above operations, an image can be displayed on the pixel array ARY.

When displaying an image in the wide mode, black display is performed at the upper and lower positions of the 4: 3 screen as shown in FIG. At this time, during the vertical retrace period of the video signal DAT, a signal voltage corresponding to black display of the video signal DAT is added to the precharge potential PCV, and the precharge circuit PC supplies the data signal line. On the other hand, the clock signal CK of the scanning signal line driving circuit
G is driven at four times the frequency of the clock signal CKG in the display area, and the pulse width control signal PWC is also input at four times the frequency to drive the scanning signal lines. Video signal DAT supplied to data signal line from precharge circuit PC
Is written to the pixel to form a black display area.

These timing charts are shown in FIGS. 13 and 14, the video signal DAT is synchronized with the clock signal CKS (not shown) and the data start signal SPS of the data signal line drive circuit SD.
Is entered. In this example, the driving method of the horizontal line inversion method is adopted, and the effective display period 1H in the wide mode.
In order to thin out the data, there is a portion where the gate scanning is stopped, and it is inverted every line on the screen. Scan signal line GL _2j-1 (j = 15 to (n / 2-1
4) However, a video signal of a positive polarity is written to a line corresponding to (n is an even number), and a video signal of a negative polarity is written to a line corresponding to the scanning signal _GL2j . In the horizontal flyback period, the data signal line SDLi (i = 1 to m) is charged with the precharge potential PCV by the precharge control signal PCC. The polarity of the precharge potential PCV is the same as the polarity of the video signal DAT to be written next.

However, in the above-mentioned image display device, the provision of the current amplifier Buffer enables the precharge potential PCV to be stably supplied.
There is a problem that power consumption by r increases.

As means for solving this problem, the present applicant has disclosed in Japanese Patent Application No. 11-300415 a precharge potential stabilizing means a passive element (in one example, a resistor R for suppressing a current and a charge holding resistor). An image display device which is configured by a pre-charging potential stabilizing circuit including a capacitor C) for preventing the fluctuation of the pre-charging potential PCV and reducing power consumption has been proposed.

[0015]

SUMMARY OF THE INVENTION The image display device comprises:
Since the pre-charge potential stabilizing means is composed of passive elements,
Although there is an advantage that the potential fluctuation of the pre-charge potential PCV can be prevented and the power consumption can be reduced by the pre-charge potential stabilizing circuit, a conventional image display device having an aspect ratio of 16: 9 is displayed on an image display device having an aspect ratio of 4: 3. When the driving method is applied, the scanning signal is generated before the capacitor C for holding the electric charge is sufficiently charged by the pre-charging potential PCV, and reaches the signal voltage corresponding to the black display of the originally required video signal DAT. It has been clarified that there is a problem that no voltage is written to the pixel and image quality deteriorates. This problem also occurs when displaying an image having an aspect ratio of 4: 3 on an image display device having an aspect ratio of 16: 9.

Therefore, the present invention relates to an image display device having a display unit and a driving circuit integrally formed on the same substrate, and having a pre-charge potential stabilizing means before the pre-charge circuit. Even when a pre-charge potential stabilizing circuit including passive elements is used as the pre-charge potential stabilizing means, it is necessary to realize a non-matched image display mode without deteriorating image quality and to reduce power consumption. This is a basic issue.

[0017]

According to the present invention, there is provided a pre-charge potential stabilizing circuit comprising passive elements as pre-charge potential stabilizing means for suppressing fluctuation of a pre-charge potential PCV. In the non-matching image display mode, when performing display at a constant luminance in the video data non-display area set on a part of the screen of the display unit by the pre-charge potential input from the pre-charge circuit, a scan signal for a certain period. Is to be stopped.

More specifically, the method for driving an image display device according to the present invention comprises a plurality of pixels arranged in a matrix, a plurality of data signal lines arranged in each column of the pixels, and a plurality of pixels. It has a plurality of scanning signal lines arranged corresponding to each row, and displays an image by supplying a video signal to each pixel from each data signal line corresponding to a scanning signal supplied from each scanning signal line. A display unit, a data signal line driving circuit that outputs video signals to the plurality of data signal lines in synchronization with a predetermined timing signal, a scanning start signal, an output signal synchronized with the scanning timing signal, and a signal width of the output signal A scanning signal line driving circuit that outputs a scanning signal to the plurality of scanning signal lines by a pulse width control signal that controls
A pre-charge circuit for charging the plurality of data signal lines with a pre-charge potential within a predetermined period by a pre-charge control signal; a pre-charge potential stabilizing means for stabilizing a pre-charge potential before the pre-charge circuit; In a method of driving an image display device having a control signal generation circuit for supplying a control signal to each of the circuits and controlling the operation thereof, a precharge configured by a charge holding means and a current control means as the precharge potential stabilizing means. Using a potential stabilizing circuit, a constant luminance is set by a pre-charge potential input from a pre-charge circuit to a first display area and a second display area set corresponding to the first and / or second portions of the screen of the display unit. In the display, the scanning signal is stopped for a certain period.

In the entire screen of the display unit, in the non-aligned image display mode, an area as a video data non-display area is:
It can be set arbitrarily such as at the top or bottom of the screen or both up and down, or at the left or right or both left and right of the screen. Normally, in the case of a display device having a screen with an aspect ratio of 4: 3, it is preferable to set a video data non-display area in the non-matched image display mode at an upper part and / or a lower part of the screen of the display unit. In this case, the scanning signal drive circuit is disposed on the left or right portion of the screen or on both the left and right portions. Also,
In the case of a display device having a screen with an aspect ratio of 16: 9,
The video data non-display area in the non-matching image display mode is
It is preferable to set at the left and / or right of the display screen. In this case, the scanning signal drive circuit is provided at the upper or lower part of the screen or both upper and lower parts.

In the non-matched image display mode, the fixed luminance to be displayed in a video data non-display area set on a part of the screen of the display unit, for example, the upper display area and the lower display area is not necessarily a luminance corresponding to black. The brightness can be set to any brightness corresponding to the brightness of dark blue, white, or any other color.

Further, as a driving method of the scanning signal line driving circuit, a line sequential driving method may be employed as in the embodiment described later, or a dot sequential driving method may be employed.

In a preferred embodiment, the upper and lower portions of the screen are displayed in black in the black display area of the upper portion of the screen using a precharge potential having a potential equivalent to the black display potential of the video signal input from the precharge circuit. The input of the scanning start signal to the scanning signal line driving circuit is stopped for a certain period. In another embodiment, when a black display is performed by a precharge potential having a potential corresponding to a black display potential of a video signal input from a precharge circuit in a black display area at an upper part of a screen, the scanning signal line driving is performed. The input of the scan start signal and the input of the scan timing signal to the circuit are stopped for a certain period.

As means for stopping the scanning signal,
Although various methods can be adopted, the input of the scan start signal may be stopped for a certain period, or the input of the scan timing signal may be stopped for a certain period together with the input of the scan start signal. Further, as means for stopping the scanning signal, the input of the scanning timing signal and the pulse width control signal may be stopped for the predetermined period.

In another embodiment, when a black display is performed by a precharge potential having a potential corresponding to the black display potential of the video signal input from the precharge circuit in the black display area at the bottom of the screen, the scanning signal line is used. The input of the scanning timing signal to the driving circuit and the pulse width control signal are stopped for a certain period.

The fixed period during which the scanning signal is stopped may be set to be equal to or greater than the time constant of the current control means and the charge holding means constituting the pre-charge potential stabilizing circuit. Further, the predetermined period may be longer than the time until the precharge potential is sufficiently stabilized.

The switching element constituting each circuit and each pixel may be a single crystal silicon transistor,
Although a polycrystalline silicon thin film transistor can be used, it is preferable to use the latter to form a precharge circuit, a data signal line driving circuit, a scanning signal driving circuit, and each pixel on the same substrate. This is because, when an element is manufactured using single crystal silicon, a transistor having excellent characteristics can be obtained, but it is difficult to increase the display area.In some cases, each drive circuit and pixels are formed on a separate substrate. It is necessary to connect the substrates with each signal line, which is troublesome at the time of manufacturing, and has the disadvantage that the capacity of each signal line increases. On the other hand, a polycrystalline silicon thin film transistor manufactured using a polycrystalline silicon thin film is inferior in transistor characteristics such as mobility and threshold value as compared with a single crystal silicon transistor. Although there is a drawback that the drive capability of each circuit is reduced when configuring,
The polycrystalline silicon thin film has an advantage that the area can be easily expanded as compared with the single crystal silicon, and the display area can be easily expanded by forming the switching element with the polycrystalline silicon thin film transistor. Therefore, each circuit is formed on the same substrate. This is because the number of manufacturing steps and the capacity of each signal line can be reduced.

In this case, the precharge circuit, the data signal line drive circuit, the scan signal drive circuit, and each switch element constituting each pixel may be manufactured at a process temperature of 600 degrees or less. Since each switching element is manufactured at a process temperature of 600 ° C. or less, even if an inexpensive ordinary glass substrate (a glass substrate having a strain point of 600 ° or less) is used as a substrate for forming each switching element, the No warping or bending due to the above process. As a result, it is easy to mount and it can be manufactured on a cheaper substrate, so that an image display device having a larger display area can be realized.

Accordingly, the present invention provides a precharge circuit, a data signal line drive circuit, a scan signal drive circuit and each pixel formed on a same substrate using a polycrystalline silicon thin film transistor. A pre-charge potential stabilizing circuit including a charge holding unit and a current control unit is provided at a stage preceding the circuit, and a video data non-display area that does not display video data set on a part of the screen of the display unit in a non-matching image display mode. A display device characterized in that a control signal generator for stopping a scanning signal for a certain period is provided in the control signal generation circuit when displaying at a constant luminance by the precharge potential input from the precharge circuit. Is also provided.

According to the present invention, a pre-charge potential stabilizing circuit constituted by a charge holding means and a current control means is used as pre-charge potential stabilizing means, and an upper black display area set at the upper and lower screens of the display section. When black display is performed in the lower black display area with the precharge potential input from the precharge circuit, the scanning signal is stopped for a certain period of time, so that the charge holding means of the precharge potential stabilization circuit has sufficient charge. After storing the data, the scanning signal is supplied, the pixel can be charged with the potential corresponding to the black display potential, and in the area where the video signal is displayed, the fluctuation of the precharge potential can be suppressed, and the desired potential can be charged to the data signal line. As a result, image quality degradation of the image display device can be suppressed.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention relates to an image display apparatus for displaying an image having an aspect ratio of 16: 9 on a screen having an aspect ratio of 4: 3, and an aspect ratio of 4: 3 on a screen having an aspect ratio of 16: 9. However, for simplicity of description, the embodiment will be described with reference to the accompanying drawings, taking the former as an example. FIG. 1 is a block diagram illustrating a configuration example of an image display device. In the present embodiment, an example is described in which there are 27 black display areas at the top and bottom of the screen, respectively. In this embodiment, a driving method of 1H inversion driving in which the polarity of the video signal DAT to be written to the pixel PIX switches between positive and negative every one horizontal period is used.

[0031]

Embodiment 1 The image display device shown in FIG. 1 includes a data signal line driving circuit SD, a scanning signal line driving circuit GD, a pixel array ARY, a control signal generating circuit CTL, and a pre-charging circuit P.
C and a precharge potential stabilizing circuit ST, and each pixel PIX constituting the pixel array ARY is provided with a data signal line S.
DLi (i = 1 to m) and the scanning signal line GLj (j = 1 to
n) are connected to each other. Further, the pixel PI
X, data signal line driving circuit SD, scanning signal line driving circuit G
D and the pre-charging circuit PC are on the same substrate S as described later.
It is configured on UB.

As shown in FIG. 5, the control signal generating circuit CTL includes a counter CNT for counting a reference clock (CLK), and a plurality of pairs of comparators each of which is set with a normal display timing and a wide mode timing. A CPR and a selector ST for selecting a plurality of comparator outputs; receiving various signals such as a color signal (R, G, B), a synchronization signal (Sync), a reference clock signal (CLK), and a wide mode selection signal; At the time of wide mode display, each control signal is output in accordance with the timing chart shown in FIG. 3. When the mode is not wide mode display, that is, at the time of normal display in which an image with an aspect ratio of 4: 3 is displayed on a screen with an image aspect ratio of 4: 3, Each control signal is output according to the timing chart shown in FIG. The control signal generation circuit CTL
For example, when focusing on the scanning start signal SPG, the comparator CPR_ in which the timing at the time of normal display is set
A1 and a comparator CPR_B1 in which the timing in the wide mode is set are provided. When a wide mode selection signal is input from the outside, the comparator CPR_B1 is selected by the selector ST1, and in the normal display, the comparator CPR_B1 is selected by the selector ST1. CPR_A1 is selected, and the scanning start signal SPG is controlled at the respective timings shown in FIG. 3 or FIG. Other signals CKG, P
WC is also stopped or output at the timing shown in the same manner.

As shown in FIG. 2, the scanning signal line driving circuit GD includes a shift register SR including a plurality of flip-flops F1 to Fn, and flip-flops F1 to Fn.
AND element NA that takes the NAND of adjacent outputs of
ND_G1 to NAND_Gn, and a NOR gate N for performing a NOR operation on outputs of the respective NAND gates NAND_G1 to NAND_Gn and a pulse width control signal PWC input for controlling the pulse width of the scanning signal.
Each of the scanning signal lines is composed of OR_G1 to NOR_Gn and receives a scanning start signal, a sequential output signal synchronized with a scanning timing signal, and a pulse width control signal for controlling the signal width of the sequential output signal from the control signal generation circuit CTL. GL
j to output a scanning signal.

The pre-charge potential stabilizing circuit ST
The precharge potential PC, which is composed of a current control means 11 and a charge holding means 12, is supplied from a control signal generation circuit CTL.
It charges the charge holding means 12 with V and outputs a signal voltage corresponding to black display of the video signal DAT. In the present embodiment, as shown in FIG. 5, the charge holding means 12 is constituted by a capacitor C, and the current control means 11 is constituted by a resistor R for the purpose of suppressing power consumption.

The capacitor C (capacity) of the charge holding means
May be larger than at least the total capacity of all the data signal lines SDLi. That is, the precharge control signal PC
It is only necessary to supply the charge stored in the charge holding means 12 while C is operating, and it is not necessary to supply a new charge from the control signal generation circuit CTL. Therefore, the amount of current can be suppressed and the power consumption can be reduced. Can be suppressed. In addition, the resistance R as the current control means 11 can suppress the inflow of current from the control signal generation circuit CTL (particularly, inrush current), and can suppress voltage fluctuation in the control signal generation circuit CTL.

When the pre-charge potential PCV is an AC potential, the current control means 11 and the charge holding means 12 constituting the pre-charge potential stabilization circuit ST stabilize to a sufficient potential within the cycle of the pre-charge control signal PCC. Is set to the optimal value. For example, in the case of an NTSC signal, one horizontal period (1
H) is 63.5 μs, so that the potential can be sufficiently held within that time, that is, the charge can be sufficiently stored in the charge holding means before the precharge control signal PCC operates. Thus, the values of the capacitor C and the resistor R are set. Here, the pre-charge potential stabilizing circuit S
T is 10 nF as a capacitor C and 220 as a resistor R
Ω is used. With this configuration, it is possible to sufficiently store charges in the charge holding unit before the precharge control signal PCC operates, and it becomes unnecessary to newly supply charges from the control signal generation circuit CTL. The amount of current can be suppressed, and power consumption can be suppressed.
As long as the above relationship is satisfied, the current control means 11 and the charge holding means 12 constituting the pre-charge potential stabilizing circuit ST may be configured using other electronic elements.

Next, the operation of each component will be described with reference to the timing chart of FIG. In the case of the wide mode, as described in the conventional example, a voltage corresponding to black display is supplied to the data signal line SDLi from the precharge circuit PC during the vertical blanking period of the video signal. At this time, the control signal generator CT
The precharge potential PCV from L is 63.5 μs during the horizontal period.
Capacitor C of the pre-charge potential stabilizing circuit ST
To charge. When the output potential APCV of the pre-charge potential stabilization circuit ST reaches a potential corresponding to black display of a video signal,
The pre-charge control signal PCC acts on the pre-charge circuit PC,
Precharge potential APCV is simultaneously charged to all data signal lines SDLi. At the same time, the supply of the scan start signal SPG to the scan signal drive circuit GD is stopped, and the scan signal is stopped. At this time, the control signals SPS and CKS are not supplied to the data signal line drive circuit SD, and the data signal line drive circuit SD is stopped.

Next, after the precharge potential PCV is sufficiently stabilized, the scanning signal line drive circuit GD supplies the scanning start signal SPG
Is supplied from the scanning signal line driving circuit GD to each scanning signal line GLj, whereby the switching element SW constituting the pixel PIX connected to each scanning signal line GLj is opened, and the pixel is precharged. The voltage corresponding to the black display supplied from the circuit PC is written. When writing to the pixels in the black display area is completed, each control signal SPS and video signal DAT are supplied to the data signal line driving circuit GD which has been stopped so far, and the display of an image is started.

When the image display is completed and a vertical blanking period of the video signal DAT is entered, black display at the bottom of the screen is started. FIG. 6 shows a timing chart at this time. In the case of the lower part of the screen, the scanning signal line G connected to the pixel PIX that performs black display
The output of the flip-flop Fn-27 forming the shift register SR in the scanning signal line driving circuit GD that has generated the scanning signal of the scanning signal line GLj-27 immediately before Lj-26 is input to the flip-flop Fn-26. However, the scanning timing signal CKG is stopped until the capacitor C of the pre-charge potential stabilizing circuit ST is sufficiently charged by the pre-charge potential PCV.

After the precharge potential PCV is sufficiently stabilized, the scanning timing signal CKG is supplied to the scanning signal line driving circuit GD again.
To output a scanning signal to the scanning signal line GLj, and sequentially open the switch elements constituting the pixel PIX connected to each scanning signal line, and apply a voltage corresponding to black display supplied from the pre-charging circuit PC to the pixel. Write.

As described above, the pre-charging has a potential corresponding to the black display potential of the video signal input from the pre-charging circuit in the upper black display area provided in the upper part of the screen and the lower black display area provided in the lower part of the screen. By stopping the scanning signal for a certain period when black display is performed by using the potential, the pixel can be charged with a potential corresponding to the black display potential after the charges are sufficiently stored in the charge holding means of the pre-charge potential stabilization circuit. In the signal display area, the fluctuation of the pre-charging potential is suppressed, the desired potential can be charged to the data signal line, and the liquid crystal display device having the pre-charging potential stabilizing circuit ST for low power consumption can be used even in a liquid crystal display device. Mode display can be performed well. Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

[0042]

Second Embodiment In the second embodiment, each configuration of a data signal line driving circuit SD, a scanning signal line driving circuit GD, a pixel array ARY, a pre-charging circuit PC and a pre-charging potential stabilizing circuit ST is the same as that of the first embodiment. However, unlike the first embodiment, not only the scan start signal SPG but also the scan timing signal CKG is used until the pre-charge potential APCV is sufficiently stabilized by the pre-charge potential stabilizing circuit ST when performing black display at the top of the screen. This is to stop for a certain period. The timing chart is shown in FIG.

This makes it possible to charge the pixel with a potential corresponding to the black display potential after the charge has been sufficiently stored in the charge holding means of the precharge potential stabilizing circuit, and to suppress the fluctuation of the precharge potential in the area where the video signal is displayed. In addition, a desired potential can be charged to the data signal line, so that a wide mode display can be performed favorably.

[0044]

Third Embodiment In the third embodiment, each configuration of a data signal line driving circuit SD, a scanning signal line driving circuit GD, a pixel array ARY, a pre-charging circuit PC and a pre-charging potential stabilizing circuit ST is the same as that of the first embodiment. However, the control signal generation circuit CTL
Is different from the first and second embodiments in which the scan start signal SPG and the scan timing signal CKG are stopped until the precharge potential PCV is sufficiently stabilized in the precharge potential stabilization circuit ST, as shown in the timing chart of FIG. The pulse width control signal PWC is stopped together with the scanning start signal SPG and the scanning timing signal CKG.

FIG. 4 shows a timing chart of the operation of the scanning signal line drive circuit GD in the first embodiment. However, the output of the scanning signal is not output unless the pulse width control signal PWC acts, and thus the present embodiment is not described. By stopping the pulse width control signal PWC as described above, the same effects as in the first and second embodiments can be obtained. Thus, even in the liquid crystal display device provided with the pre-charge potential stabilizing circuit ST for the purpose of reducing power consumption, wide mode display can be favorably performed.

Although the case where the scanning signal lines are sequentially scanned has been described above, the present invention is not limited to this. For example, a plurality of scanning signal lines corresponding to a black display area may be simultaneously scanned. Further, all the scanning signal lines corresponding to the black display area may be simultaneously scanned. Further, at the same time, scanning signal lines corresponding to the upper black display area and the lower black display area may be sequentially scanned. By doing so, the vertical retrace period can be effectively used, and the writing time can be secured.

[0047]

[Configuration of Image Display Apparatus] Next, the first, second, and third embodiments will be described.
The physical configuration of the image display device used in FIG. 1 will be described. As shown in FIG.
X, data signal line driving circuit SD, scanning signal line driving circuit G
D and a precharge circuit PC have a driver monolithic structure formed on the same substrate SUB, and the precharge circuit PC, the data signal line drive circuit SD, and the scan signal line drive circuit GD are formed by a pixel array ARY. They are widely distributed and arranged in a region having substantially the same length as the screen (display unit). Further, the control signal generation circuit CTL and the pre-charge potential stabilization circuit ST are provided outside and connected to each circuit by a signal line.

Each circuit is composed of, for example, a polycrystalline silicon thin film transistor shown in FIG. The illustrated polycrystalline silicon thin film transistor has a forward stagger (top gate) structure in which the polycrystalline silicon thin film on the insulating substrate 1 is used as the active layer 2, but the polycrystalline silicon thin film transistor in the present invention is not limited to this. Not a thing,
Another structure such as an inverted stagger structure may be used.

The polycrystalline silicon thin film transistor having the above structure can be manufactured by, for example, a manufacturing method including steps (a) to (k) shown in FIG. That is, first, an insulating substrate 1 made of glass or the like is prepared as shown in (a), and an amorphous silicon thin film (a-Si) is deposited on the substrate as shown in (b). Next, as shown in (c), the film deposited on the substrate 1 is irradiated with an excimer laser to form a polycrystalline silicon thin film (poly-Si). Next, as shown in (d), the polycrystalline silicon thin film (poly-Si) is patterned into a desired shape. Next, as shown in (e), a gate insulating film 3 made of silicon dioxide is formed so as to cover the patterned polycrystalline silicon thin film 2. Further, as shown in (f), the gate electrode 4 of the thin film transistor is formed of aluminum or the like. Thereafter, as shown in (g, h), after a resist 5 is provided in a portion where the impurity is not implanted, impurities are added to the source / drain region of the thin film transistor (phosphorus P · in the n-type region and boron to the p-type region). Ions B) are implanted. The source / drain regions become a source electrode 6 and a drain electrode 7, respectively. Thereafter, as shown in (i), an interlayer insulating film 8 made of silicon dioxide or silicon nitride is deposited. Next, as shown in (j), a contact hole 9 is opened in the interlayer insulating film 8 and the gate insulating film 3. Finally, as shown in (k), a metal wiring 10 of aluminum or the like is formed. In a liquid crystal display device, a transparent electrode is formed in the case of a transmissive liquid crystal display device, and a reflective electrode is formed in the case of a reflective liquid crystal display device, via another interlayer insulating film.

In the above manufacturing method, since the maximum temperature of the process is 600 ° C. at the time of forming the gate insulating film, the strain point is 60 ° C.
Even when a glass substrate at a temperature of 0 ° C. or lower is used, no warping or bending due to a process at a strain point or higher occurs, and a high heat-resistant glass (for example, Corning 17
37 glass) or a normal glass substrate having a strain point of 600 ° C. or less.

[0051]

As is apparent from the above description, the present invention relates to a method for driving an image display apparatus having a pre-charge potential stabilizing means before a pre-charge circuit, comprising a charge holding means and a current control means. Using the precharge potential stabilizing means, the upper black display area provided at the upper part of the screen and the lower black display area provided at the lower part of the screen have a potential corresponding to the black display potential of the video signal input from the precharge circuit. When black display is performed by the pre-charge potential, the scanning signal is stopped for a certain period of time. Therefore, after sufficiently storing charges in the charge holding means of the pre-charge potential stabilizing circuit, the potential corresponding to the black display potential is applied to the pixel. In the area where the video signal is displayed, the fluctuation of the pre-charge potential can be suppressed, and the desired potential can be charged to the data signal line, thereby suppressing the image quality deterioration of the image display device. Requires no current amplifying circuit, it is possible to suppress an increase in power consumption.

In the method for driving an image display device according to the present invention, when black display is performed in the black display area at the top of the screen using a precharge potential having a potential equivalent to the black display potential of the video signal input from the precharge circuit. Then, in order to stop the scanning signal, the input of the scanning start signal is stopped for the above-mentioned fixed period, so that the charges are sufficiently stored in the charge holding means of the pre-charge potential stabilizing circuit. In the area where the potential can be charged and the video signal is displayed, the fluctuation of the pre-charge potential can be suppressed, the desired potential can be charged to the data signal line, and the deterioration of the image quality of the image display device can be suppressed. Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

In the driving method of the image display device according to the present invention, when black display is performed by a preliminary charging potential having a potential corresponding to the black display potential of the video signal input from the preliminary charging circuit in the black display area at the top of the screen. In order to stop the scanning signal, by stopping the input of the robbery start signal and the input of the scanning timing signal for a certain period of time, after sufficiently storing the charges in the charge holding means of the pre-charge potential stabilizing circuit, the pixel In an area where a video signal is displayed, a potential corresponding to a black display potential can be charged, and in an area where a video signal is displayed, fluctuation of a precharge potential can be suppressed, and a desired potential can be charged to a data signal line, thereby suppressing deterioration in image quality of an image display device. be able to. Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

In the method of driving an image display device according to the present invention, when black display is performed in a black display area at a lower portion of a screen by a precharge potential having a potential equivalent to a black display potential of a video signal input from a precharge circuit. By stopping the input of the scan timing signal and the pulse width control signal for a certain period to stop the scanning signal, the pixel is displayed in black after the charge is sufficiently stored in the charge holding means of the pre-charge potential stabilizing circuit. In the area where the potential corresponding to the potential can be charged and in the area where the video signal is displayed, the fluctuation of the pre-charge potential can be suppressed, the desired potential can be charged to the data signal line, and the deterioration of the image quality of the image display device can be suppressed. . Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

In the driving method of the image display device according to the present invention, the time constant of the current control means and the charge holding means constituting the precharge potential stabilizing circuit is maintained for a predetermined period during which the scanning start signal, the scanning timing signal, and the pulse width control signal are stopped. As described above, the potential corresponding to the black display potential of the video signal can be sufficiently stored in the charge holding means of the precharge potential stabilizing circuit. As a result, the potential equivalent to the black display potential can be charged to the pixel after the charge has been sufficiently stored in the charge holding means of the precharge potential stabilizing circuit, and the fluctuation of the precharge potential is suppressed in the area where the video signal is displayed. In addition, a desired potential can be charged to the data signal line, and deterioration in image quality of the image display device can be suppressed. Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

In the method for driving an image display device according to the present invention, the predetermined period is set to be equal to or longer than the time until the precharge potential is sufficiently stabilized, so that the precharge having a potential equivalent to the black display potential of the video signal is performed. The potential can be sufficiently stored in the charge holding means of the precharge potential stabilizing circuit. As a result, the pixel can be charged with a potential corresponding to the black display potential after the charges have been sufficiently stored in the charge holding means of the pre-charge potential stabilizing circuit, and the fluctuation of the pre-charge potential is suppressed in the area where the video signal is displayed. In addition, a desired potential can be charged to the data signal line, and deterioration in image quality of the image display device can be suppressed. Further, since a current amplifier circuit is not required, an increase in power consumption can be suppressed.

Further, a pre-charging circuit PC of the image display device,
By forming the switching elements constituting the data signal line driving circuit SD, the scanning signal line driving circuit GD, and the pixel PIX from a polycrystalline silicon thin film, each circuit is approximately 600 ° C.
Can be manufactured in the following manner, and therefore, a conventional glass (having a strain point of 60
0 ° C. or lower glass) can be used as the substrate,
An inexpensive and large-area image display device can be realized.

Further, by using the polycrystalline silicon thin film transistor, the pre-charging circuit PC, the data signal line driving circuit SD and the scanning signal line driving circuit GD having practical driving capabilities are substantially the same on the same substrate SUB as the pixel PIX. The manufacturing process and the mounting cost of the drive circuit can be reduced as compared with the case where the components are separately configured and mounted, and the reliability can be improved. Furthermore, since it can be easily formed on the same substrate SUB, the labor and the capacity of each signal line at the time of manufacturing can be reduced. In addition, since the pre-charging circuit PC, the scanning signal line driving circuit GD, and the data signal line driving circuit SD are used, it is possible to realize green space reduction and reduction in power consumption by reducing the circuit scale.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration example of an image display device according to the present invention.

FIG. 2 is a diagram showing a timing chart in the image display device according to the first embodiment of the present invention.

FIG. 3 is a detailed diagram of a scanning signal line driving circuit used in the driving method of the image display device of the present invention.

FIG. 4 is a timing chart in a normal mode of a scanning signal line driving circuit used in the driving method of the image display device of the present invention.

FIG. 5 is a block diagram showing a main part of a control signal generation circuit and a configuration of a precharge potential stabilization circuit;

FIG. 6 is a diagram showing a timing chart when black display is performed at a lower portion of a screen according to the first embodiment.

FIG. 7 is a diagram showing a timing chart in the image display device according to the second embodiment of the present invention.

FIG. 8 is a diagram showing a timing chart in the image display device according to the third embodiment of the present invention.

FIG. 9 is a diagram showing a configuration of a polycrystalline silicon thin film transistor constituting the image display device of the present invention.

FIG. 10 is a diagram showing a manufacturing process of a polycrystalline silicon thin film transistor.

FIG. 11 is a block diagram showing a configuration of a conventional image display device.

FIG. 12 is a diagram illustrating a configuration of a pixel PIX.

FIG. 13 is a diagram showing drive waveforms when displaying an upper portion of a screen in black in a conventional image display device.

FIG. 14 is a diagram showing a driving waveform when a lower portion of a screen is displayed in black in a conventional image display device.

FIG. 15 is a diagram showing a case where a 16: 9 image is displayed on an image display device having an aspect ratio of 4: 3 by displaying black on the upper and lower portions of the screen.

FIG. 16 is a diagram when a 16: 9 image is displayed on an image display device having an aspect ratio of 4: 3 by deleting the left and right portions of the screen.

[Explanation of symbols]

 ARY Pixel array C Capacitor CKG, CKS Clock signal CL Liquid crystal capacitance Cs Auxiliary capacitance CTL Control signal generation circuit DAT Video signal GD Scan signal line drive circuit GLj Scan signal line PC Precharge circuit PCC Precharge control signal PCV Precharge potential PIX Pixel R Resistance SD Data signal line drive circuit SDLi Data signal line SPG Scan start signal SPS Data start signal ST Precharge potential stabilization circuit SUB Same substrate SW Switch element TA TB Interval Vcom Opposing potential

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/36 G09G 3/36 H04N 5/66 H04N 5/66 B (72) Inventor Hiroshi Yoneda Osaka, Osaka 22-22 Nagaikecho, Abeno-ku, Japan F-term (reference) 2H093 NA16 NA31 NA43 NC09 NC11 NC90 ND39 ND60 5C006 AA01 AA16 AC22 AF42 AF69 BB16 BC13 BF03 BF11 FA47 FA56 5C058 AA08 BA22 BA26 BA35 BB06 BB19 A35 DD03 DD26 EE29 FF11 GG08 JJ02 JJ04 JJ06

Claims (11)

[Claims] 1. A semiconductor device comprising: a plurality of pixels arranged in a matrix; a plurality of data signal lines arranged in each column of the pixels; and a plurality of scanning signal lines arranged corresponding to each row of the pixels. A display unit that displays an image by supplying a video signal to each pixel from each data signal line in accordance with a scanning signal supplied from each scanning signal line; and a display unit that displays the image in synchronization with a predetermined timing signal. A plurality of scanning signal lines that are scanned by a data signal line driving circuit that outputs a video signal to a signal line, an output signal synchronized with a scanning start signal and a scanning timing signal, and a pulse width control signal that controls a signal width of the output signal; A scanning signal line driving circuit for outputting a signal,
A precharge circuit for charging the plurality of data signal lines with a precharge potential within a predetermined period by a precharge control signal; a precharge potential stabilizing means for stabilizing a potential supplied by the precharge circuit; A method for driving an image display device comprising a control signal generating circuit for supplying a control signal to each circuit and controlling the operation thereof, wherein a pre-charge potential stabilizing circuit comprising a charge holding means and a current control means as said pre-charge potential stabilizing means And a constant brightness by a pre-charge potential input from a pre-charge circuit to a first display area and / or a second display area set corresponding to a first part and / or a second part of a screen of the display unit. A driving method for stopping a scanning signal for a certain period when performing display by using the method. 2. The driving method according to claim 1, wherein the input of the scanning start signal to the scanning signal line driving circuit is stopped for a certain period to stop the scanning signal. 3. The scanning signal line driving circuit according to claim 1, wherein the input of the scanning start signal and the input of the scanning timing signal to the scanning signal line driving circuit are stopped for the predetermined period to stop the scanning signal. The driving method described. 4. The apparatus according to claim 1, wherein in order to stop the scanning signal, input of a scanning timing signal to the scanning signal line driving circuit and a pulse width control signal are stopped for the predetermined period. Drive method. 5. The driving method according to claim 1, wherein the predetermined period is equal to or longer than a time constant of a current control unit and a charge holding unit constituting the pre-charge potential stabilizing circuit. . 6. The driving method according to claim 1, wherein the predetermined period is equal to or longer than a time until the precharge potential is sufficiently stabilized. 7. A plurality of pixels arranged in a matrix, a plurality of data signal lines arranged in each column of the pixels, and a plurality of scanning signal lines arranged corresponding to each row of the pixels. A display unit that displays an image by supplying a video signal to each pixel from each data signal line in accordance with a scanning signal supplied from each scanning signal line; and a display unit that displays the image in synchronization with a predetermined timing signal. A plurality of scanning signal lines that are scanned by a data signal line driving circuit that outputs a video signal to a signal line, an output signal synchronized with a scanning start signal and a scanning timing signal, and a pulse width control signal that controls a signal width of the output signal; A scanning signal line driving circuit for outputting a signal,
A precharge circuit for charging the plurality of data signal lines with a precharge potential within a predetermined period by a precharge control signal; a precharge potential stabilizing means for stabilizing a potential supplied by the precharge circuit; An image display device comprising a control signal generating circuit for supplying a control signal to each circuit and controlling the operation thereof, wherein the pre-charge potential stabilizing means comprises a pre-charge potential stabilizing circuit comprising a charge holding means and a current control means. In the non-matching image display mode, a part of the display unit is set as a video data non-display area where no video data is displayed, and the video data non-display area is fixed by a precharge potential input from a precharge circuit. When displaying with brightness,
An image display device, wherein a control signal generation unit for stopping a scanning signal for a predetermined period is provided in the control signal generation circuit. 8. The apparatus according to claim 7, wherein said predetermined period is equal to or longer than a time constant of current control means and charge holding means constituting said precharge potential stabilizing circuit. 9. The image display device according to claim 7, wherein the precharge circuit, the data signal line driving circuit, the scanning signal driving circuit, and each pixel are formed on the same substrate. 10. The precharge circuit, the data signal line drive circuit, the scan signal drive circuit, and the switch element forming each pixel are formed of a polycrystalline silicon thin film transistor. The image display device as described in the above. 11. The semiconductor device according to claim 7, wherein the precharge circuit, the data signal line drive circuit, the scan signal drive circuit, and each switch element constituting each pixel are manufactured at a process temperature of 600 degrees or less. 11. The image display device according to any one of 10.