JPH09101764A - Driving method for matrix type video display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video display which is free from display distortion for a video signal with an arbitrary 2nd aspect ratio and secures a video data display rate of practical level. SOLUTION: In the display screen of the matrix video display device with a 1st aspect ratio, a 1st video display area 8 with a 2nd aspect ratio for making a video display with a video signal with the 2nd aspect ratio and a 2nd video display area 9 as an area other than the 1st video display area 8 are set, and a black display is made in the 2nd video display area 9. As the timing design of a vertical clock signal N and a horizontal clock signal Q, a timing design which equalizes the aspect ratio of the 1st video display area 8 to the aspect ratio of a video signal H is employed. The vertical scanning of the video display device 4 is performed by setting the vertical scanning frequency of the 2nd video display area 9 higher than the vertical scanning frequency of the 1st video display area 8. The horizontal scanning of the video display device 4 is performed by setting the horizontal scanning frequency of the 2nd video display area 9 higher than the horizontal scanning frequency of the 1st video display area 8.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving method of a matrix type image display device capable of displaying an image without display distortion for an image signal having an arbitrary aspect ratio.

[0002]

2. Description of the Related Art A general driving method of a conventional matrix type image display device will be described below.

FIG. 6 is a diagram for explaining a driving method of a matrix type image display device in the prior art, and FIG. 7 is a block diagram showing a driving circuit of a conventional matrix type image display device. As shown in FIG. 7, the drive circuit of the matrix-type image display device (hereinafter referred to as “image display device”) 1 includes a synchronization signal generator 13 that outputs a composite synchronization signal B and a synchronization signal from the synchronization signal generator 13. The timing controller 2 receives the signal B and outputs a drive signal C for driving the video display device 1.

As shown in FIG. 6, the drive signal C includes a vertical start signal D that determines the start timing of the vertical image display period, a vertical clock signal E that performs vertical scanning, and a start timing of the horizontal image display period. And a horizontal clock signal G for performing horizontal scanning, and the vertical clock signal E and the horizontal clock signal G are set to a single scan frequency.

As shown in FIG. 7, the image display device 1 receives the image signal A from the image signal output device 14 and the drive signal C from the timing controller 2, and displays an image on the display screen 3 (FIG. 6). indicate. In this case, in the vertical drive of the video display device 1, as shown in FIG. 8, the video data included in the video signal A is converted into the vertical start signal D and the vertical clock signal E.
It is performed by controlling by and. Further, as shown in FIG. 9, the horizontal drive of the video display device 1 is performed by the video signal A
Is controlled by the horizontal start signal F and the horizontal clock signal G.

Generally, in a video display device, when a video signal having an aspect ratio different from that of the display screen of the display device is received and the video is displayed over the entire area of the display screen, the aspect ratio of the display screen and the video Display distortion occurs in the entire image display due to the mismatch of the aspect ratios of the signals. For example, when the liquid crystal display device is compatible with a video signal having an aspect ratio of 4: 3, when a wide video signal having an aspect ratio of 16: 9 is reproduced, a vertically distorted video image is displayed.

The configurations of FIGS. 6 and 7 correspond to the case where the video signal A is fixed to one aspect ratio. That is, the configurations of FIG. 6 and FIG.
Is designed so that the aspect ratio of the display screen 3 is equal to the aspect ratio of the video signal A, and when the video by the video signal A is displayed over the entire area of the display screen 3, it is possible to display a video without display distortion. It was made possible.

[0008]

In recent years, the display aspect ratio of video display devices, including audiovisual (AV) devices, has been changed from the conventional 4: 3 to wide (for example, 1).
It is diversifying, including the transition to 6: 9).

However, the above-mentioned conventional driving method of the matrix type image display device realizes the image display without display distortion only for the image signal having one aspect ratio. That is, the above-mentioned conventional driving method does not support the diversification of the display aspect ratio in the above-mentioned video display device.

In order to solve the above problems in the prior art, the present invention relates to a video signal having an arbitrary aspect ratio,
It is an object of the present invention to provide a driving method of a matrix type video display device capable of realizing video display without display distortion.

[0011]

In order to achieve the above object, a method of driving a matrix type image display device according to the present invention comprises a display screen having a first aspect ratio, and an arbitrary second aspect in the display screen. A first image display area having a second aspect ratio for displaying an image by a ratio image signal is set, and a second image display area other than the first image display area in the display screen is fixed with a constant color. A driving method of a matrix type image display device which is used as an area for displaying an image with the luminance of 1. The scan frequency of the second image display area is higher than the scan frequency of the first image display area. To do.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION According to the method for driving a matrix type image display device of the present invention, a display screen having a first aspect ratio is provided, and an image is displayed on the display screen by a video signal having an arbitrary second aspect ratio. The first video display area having the second aspect ratio is set, and the second video display area other than the first video display area in the display screen performs video display with a constant color and a constant luminance. A method for driving a matrix-type image display device defined as a region, wherein the scan frequency of the second image display region is set to be higher than the scan frequency of the first image display region, so that the following operation is achieved. You can That is, a first image display area having a second aspect ratio for displaying an image with an image signal having an arbitrary second aspect ratio is set on the display screen, and a first image display area other than the first image display area on the display screen is set. Since the two video display areas are areas for performing video display with a constant color and a constant luminance, a video image with an arbitrary second aspect ratio video signal can be displayed in the first video display area without causing display distortion. Can be displayed on.

When the horizontal (and vertical) data display rate of the video display is not 100% with respect to the video data within one horizontal (and one vertical) period included in the video signal, the video display is the A part of the video data of the signal is deleted. Therefore, if the video data display ratio is smaller than a certain allowable value, the video information of the video signal is not displayed in a practical amount of information by the video display device. Generally, the tolerance is about 90%,
The above problem does not occur at horizontal (and vertical) data display ratios above this allowable value. That is, the video data display rate equal to or higher than the allowable value is referred to as "practical level video data display rate". If such a practical level of video data display rate is secured, in the horizontal (and vertical) driving of the video display device, the horizontal (and vertical) scan period of the first video display area for displaying video is one horizontal (and vertical). Since most of one vertical period is occupied, the horizontal (and vertical) scanning period of the second image display area must be included in the remaining horizontal (and vertical) display blanking period. However, according to the conventional driving method using a single horizontal (and vertical) scan frequency, the horizontal (and vertical) scan period of the second image display area is replaced by the remaining horizontal (and vertical) display blocks of one horizontal (and one vertical) cycle. Since it is not possible to fit within the ranking period, it is not possible to achieve both the video display at the practical level video data display ratio in the first video display area and the video display in the second video display area. On the other hand, according to the driving method of the matrix type image display device of the present invention, the horizontal (and vertical) direction of the second image display area is
By setting the scan frequency higher than the horizontal (and vertical) scan frequency of the first image display area, the horizontal (and vertical) scan frequency of the second image display area can be compressed at an arbitrary time. 2 horizontal (and vertical) scan periods of 1 image (1 vertical)
It can fit within the remaining horizontal (and vertical) display blanking period of the cycle. As a result, it is possible to achieve both the video display at the practical level video data display ratio in the first video display area and the video display in the second video display area.

As described above, according to the driving method of the matrix type image display device of the present invention, there is no display distortion with respect to the image signal of the arbitrary second aspect ratio, and the image data is displayed at a practical level. It is possible to realize a video display with a secured rate.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail below with reference to embodiments. <First Embodiment> FIG. 1 illustrates a first embodiment of a driving method for a matrix type image display device according to the present invention. FIG. 2 is a block diagram showing a drive circuit used in the first embodiment of the present invention. As shown in FIG. 1, a display screen 7 having a first aspect ratio in a matrix type video display device (hereinafter referred to as “video display device”) 4 (FIG. 2) has a video signal H of a second aspect ratio (see FIG. 2) a first image display area 8 having a second aspect ratio for displaying an image,
A second video display area 9, which is an area other than the video display area 8, is set, and black display is performed in the second video display area 9.

As shown in FIG. 2, the drive circuit of the image display device 4 includes a sync signal generator 15 for outputting a composite sync signal J.
And a timing controller 6 which receives a synchronization signal J from the synchronization signal generator 15 and outputs a drive signal K for driving the video display device 4 and a control signal L for controlling the analog switch 5. ing.
In this case, the first video display area 8 (FIG. 1) displays a video based on the video signal H, and the second video display area 9 (FIG. 1) performs black display. Switching between both images in the image display area 9 is performed by switching the image signal H from the image signal output device 16 and the black signal I from the black signal output device 17 by the analog switch 5.

As shown in FIG. 1, the drive signal K includes a vertical start signal M for determining the start timing of a vertical image display period, a vertical clock signal N for performing a vertical scan, and a horizontal image display period start timing. And a horizontal clock signal Q for performing horizontal scanning. In this case, as the timing design of the vertical clock signal N and the horizontal clock signal Q, a timing design in which the aspect ratio of the first video display area 8 is equal to the aspect ratio of the video signal H (FIG. 2) is adopted.

Next, a method of driving the image display device having the above-mentioned structure will be described. Sync signal generator 15
When the synchronization signal J is output from the timing controller 6, the timing controller 6 outputs the control signal L to the analog switch 5. The analog switch 5 receives the control signal L from the timing controller 6 and receives the video signal output device 1
Video signal H from 6 and black signal I from black signal output device 17
Is output to the video display device 4 while being switched at any time. Further, the timing controller 6 includes a synchronization signal generator 15
The drive signal K is output to the video display device 4 in response to the synchronization signal J from the. As a result, a video based on the video signal H having the second aspect ratio is displayed in the first video display area 8 having the second aspect ratio, and black display is performed in the second video display area 9. In this case, the vertical drive of the image display device 4 is
It is performed by controlling with the vertical start signal M and the vertical clock signal N. The horizontal drive of the video display device 4 is performed by controlling the horizontal start signal P and the horizontal clock signal Q.

As described above, the first image display area 8 having the second aspect ratio displays the image by the image signal H having the second aspect ratio, and the second image display area 9 displays the black image. It is possible to display an image based on the image signal H having the 2 aspect ratio on the first image display area 8 without causing display distortion. In this case, since the second aspect ratio can be set arbitrarily, it is possible to realize video display without display distortion for a video signal having an arbitrary aspect ratio.

By the way, as shown in FIG. 3 (and FIG. 4), the horizontal (and vertical) data display ratio of the video display with respect to the video data within one horizontal (and one vertical) period included in the video signal H. Is not 100%, the video display is in a state where the video data of the video signal is partially deleted.
Therefore, when the video data display ratio is smaller than a certain allowable value, the video information of the video signal is not displayed by the video display device 4 in a practical amount of information.
Generally, the allowable value is about 90%, and the above problem does not occur at a horizontal (and vertical) data display rate higher than the allowable value. That is, the video data display rate equal to or higher than the allowable value is referred to as "practical level video data display rate". If you secure such a practical level video data display rate,
As shown in FIG. 3 (and FIG. 4), in the horizontal (and vertical) driving of the video display device, the horizontal (and vertical) scan period of the first video display area 8 for displaying a video is one horizontal (and one vertical). ) Most of the period is occupied, and the horizontal (and vertical) scan period of the second video display area 9 must be included in the remaining horizontal (and vertical) display blanking period. But traditional single horizontal (and vertical)
In the driving method using the scan frequency, the horizontal (and vertical) scan period of the second video display area 9 cannot be accommodated within the remaining horizontal (and vertical) display blanking period of one horizontal (and one vertical) cycle. It is not possible to achieve both the video display at the practical level video data display ratio in the first video display area 8 and the video display in the second video display area 9.

In order to solve this problem, the following driving method is adopted in this embodiment. The vertical scan of the video display device 4 is performed by the vertical clock signal N of FIG.
As shown in, the vertical scanning frequency of the second video display area 9 is set higher than the vertical scanning frequency of the first video display area 8. As a result, the vertical scan time of the second video display area 9 is compressed and the first video display area 9 is displayed.
Even when the vertical scanning period of the video display area 8 occupies most of one vertical cycle, the vertical scanning period of the second video display area 9 is set within the remaining blanking period of one vertical cycle. Since it can be accommodated, the video signal H
On the other hand, the vertical scan timing that secures the video data display rate of a practical level is realized.

Similarly, in the horizontal scan of the video display device 4, as shown by the horizontal clock signal Q in FIG. 1, the horizontal scan frequency of the second video display area 9 is set to the first video display area 8.
The horizontal scanning frequency is set to be higher than the horizontal scanning frequency.
As a result, even when the horizontal scan time of the second video display area 9 is compressed and the horizontal scan period of the first video display area 8 for displaying video occupies most of one horizontal cycle. Since the horizontal scan period of the second video display area 9 can be accommodated within the remaining blanking period of one horizontal cycle, horizontal scan timing that secures a practical level of video data display rate for the video signal H is realized. To be done.

As described above, by setting the horizontal (and vertical) scan frequency of the second video display area 9 higher than the horizontal (and vertical) scan frequency of the first video display area 8, the first video display area 8 is obtained. It is possible to achieve both the video display of the horizontal (and vertical) video data display rate of the practical level by the video signal H in 8 and the video display of the second video display area 9.

Therefore, according to the driving method of the matrix type image display device of the present embodiment, there is no display distortion with respect to the image signal of an arbitrary aspect ratio, and a practical level image data display rate is secured. Video display can be realized.

<Second Embodiment> FIG. 5 is a view for explaining a second embodiment of the driving method of the matrix type image display device according to the present invention.

As shown in FIG. 5, on the display screen 10 having the aspect ratio of 16: 9 in the matrix type image display device, the first aspect ratio of 4: 3 for performing image display by the image signal of the aspect ratio of 4: 3. The image display area 11 is set to have the largest possible area. Also, the display screen 10
Black display is performed in the second video display area 12, which is an area other than the first video display area 11. That is, in this video display device, black display is performed only at the left and right ends. Therefore, the vertical clock signal S is set to a single vertical scan frequency. Further, the horizontal clock signal U has a horizontal scan frequency of the second video display area 12 equal to 2 of the horizontal scan frequency of the first video display area 11.
It is set to double (specific example: the horizontal scan frequency of the first video display area 11 is 2.14 MHz, and the horizontal scan frequency of the second video display area 12 is 4.28 MH).
z). As a result, the horizontal scan time of the second video display area 12 is compressed with respect to the horizontal scan at the single horizontal scan frequency, so that a video display with a practical level of video data display ratio is secured in the first video display area 11. Even if the horizontal scanning period of the first video display area 11 occupies most of one horizontal period in order to perform the above, the horizontal scanning period of the second video display area 12 is set to 1
It is possible to fit within the remaining horizontal display blanking period of the horizontal cycle. That is, it is possible to make the video display in the first video display area 11 which is a practical level video data display rate compatible with the video display in the second video display area 12. Therefore, according to the driving method of the matrix type image display device of the present embodiment, there is no display distortion with respect to the image signal having the aspect ratio of 4: 3, and the image display with a practical level of image data display ratio is secured. Can be realized.

According to this driving method, the same image display device as the 16:
This is effective when used as a video display terminal of a device that handles video signals of two types of aspect ratios of 9 and 4: 3.
In the first and second embodiments described above, the black display is performed in the second video display area other than the first video display area in which the video signal is displayed by the video signal, but it is not limited to the black display. Instead, it is only necessary to display an image with a certain color and a certain luminance.

Further, in the present invention, "to make the scan frequency of the second image display area higher than the scan frequency of the first image display area" is a relative thing,
If the scan frequency of the first image display area is set high,
Therefore, the scan frequency of the second image display area also needs to be increased.

[0029]

As described above, according to the driving method of the matrix type image display device of the present invention, the image of the second aspect ratio is displayed on the display screen by the image signal of the arbitrary second aspect ratio. Since the first video display area is set and the second video display area other than the first video display area in the display screen is an area for performing video display with a constant color and a constant luminance, It is possible to display an image of an image signal having an arbitrary second aspect ratio in the first image display area without causing display distortion. Further, the horizontal (and vertical) scan frequency of the second image display area is set higher than the horizontal (and vertical) scan frequency of the first image display area, so that the horizontal (and vertical) scan frequency of the single horizontal (and vertical) scan frequency is increased. ) Second for scan
The horizontal (and vertical) scan time of the image display area can be compressed to an arbitrary time. Therefore, the horizontal (and vertical) scan period of the first video display area is large by one horizontal (and one vertical) cycle in order to perform video display in the first video display area while ensuring a video data display rate of a practical level. Even when the area is occupied, the horizontal scan period of the second video display area can be included in the remaining horizontal (and vertical) display blanking period. That is,
It is possible to achieve both the video display having the video data display rate of the practical level in the first video display area and the video display in the second video display area. Therefore, there is no display distortion for the input video signal of an arbitrary aspect ratio, and
It is possible to realize video display with a practical level of video data display rate secured.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a first embodiment of a driving method of a matrix type image display device according to the present invention.

FIG. 2 is a block diagram showing a drive circuit used in the first embodiment of the present invention.

FIG. 3 is a diagram for explaining a practical level video data display rate according to the first embodiment of the present invention.

FIG. 4 is a diagram for explaining a practical level video data display rate according to the first embodiment of the present invention.

FIG. 5 is a diagram for explaining a second embodiment of the driving method of the matrix type image display device according to the present invention.

FIG. 6 is a diagram illustrating a driving method of a conventional matrix-type image display device.

FIG. 7 is a block diagram showing a drive circuit of a conventional matrix-type image display device.

FIG. 8 is a diagram for explaining vertical driving of a matrix type image display device.

FIG. 9 is a diagram for explaining horizontal driving of a matrix-type image display device.

[Explanation of symbols]

 1, 4 Matrix type video display device 5 Analog switch 2, 6 Timing controller 3, 7, 10 Display screen 8, 11 First video display area 9, 12 Second video display area 13, 15 Sync signal generator 14, 16 video Signal output device 17 Black signal output device A, H Video signal I Black signal B, J Sync signal C, K Video display device drive signal L Analog switch control signal D, M, R Vertical start signal E, N, S Vertical clock signal F, P, T Horizontal start signal G, Q, U Horizontal clock signal

Claims (1)

[Claims] 1. A display screen having a first aspect ratio is provided, and a first video display region having a second aspect ratio for displaying a video by a video signal having an arbitrary second aspect ratio is set in the display screen, A driving method of a matrix type video display device, wherein a second video display area other than the first video display area in the display screen is an area for displaying a video with a constant color and a constant luminance, 2. A driving method of a matrix type image display device, wherein a scan frequency of the image display area is set higher than a scan frequency of the first image display area.