JPH0486083A - Display device - Google Patents

Abstract

PURPOSE:To set deterioration in an input video display part almost equal to that in a mask video display part by forming a mask part in a video of one color provided with luminance same as the mean luminance of the edge part of an input video. CONSTITUTION:A video signal SIM from the outside is inputted to a video output means 14 and a mask signal generating means 16, and the video output means 14 displays the video signal SIM on only part 11 of a display screen 10, and the mask signal generating means 18 generates the mask video signal SMK of a prescribed video signal from the video signal equivalent to the edge part of a picture being displayed in such way. As the video signal equivalent to the edge part, for example, a first scanning line or the last scanning line, etc., can be taken. Also, as the mask video signal SMK, the video signal uniformalized with the mean luminance of those scanning line signals can be employed. In such a way, no difference of deterioration between the video display part 11 and a non-display part 12 occurs even after partial video display is performed for a long time.

Description

[Detailed Description of the Invention] The present invention is applicable to CRTs (cathode ray tubes) and LEDs (light emitting diodes) that use only a portion of the screen for a long time when displaying images.
It relates to display devices such as panels.

There is an HDTV to NTSC signal conversion device for displaying a video signal sent in high-definition (hereinafter referred to as HDTV) on a current NTSC CRT. However, while an NTSC CRT has an aspect ratio of 3:4, HDTV images have an aspect ratio of 9:16, which is slightly horizontal.

Therefore, if an attempt is made to display the entire range of an HDTV image on an NTSC CRT, there will be areas 50.degree. 52 above and below the CRT screen where no image is displayed, as shown in FIG.

If all the scanning lines in this part are set to black level, the phosphor in the part 51 where the image is displayed will deteriorate due to collision with the electron beam, and when displaying the normal NTSC system image, it will deteriorate due to long-term use. Differences in color and brightness may be noticeable between the portion 51 and the portions 50 and 52 that have not deteriorated.

Therefore, in the past, a signal of a constant intermediate brightness (gray) was outputted (masked) to the upper and lower portions 50 and 52 where the HDTV images were not displayed. That is, the upper and lower mask portions 50 and 52 are also connected to the central HDT.
This means that it is degraded in the same way as the V video display portion 51.

However, the display content of the video display section 51 changes depending on the content of the HDTV video, and the degree of deterioration is not uniform. Therefore, there is still a possibility that a difference in the degree of deterioration will occur between the upper and lower mask portions 50, 52, which are masked with a constant brightness, and the central video display portion 51.

The present invention solves these problems and provides a display device that does not cause a difference in the degree of deterioration between the video display part and the non-display part even after such partial video display is performed for a long time. The purpose is to provide.

In order to achieve the above object, as shown in FIG.
In a display device that displays a screen, a predetermined mask video signal 3l- is extracted from a signal corresponding to the edge of the screen in the video signal.
A mask signal generation means 16 that generates IK and an external video signal S! . is displayed only on a portion 11 of the display screen 10, and the mask video signal S is displayed. It is characterized by comprising a video output means 14 for displaying K on the other part 12 of the display screen 10.

During production, the external video signal S1° is input to the video output means 14 and the mask signal generation means 16. The video output means 14 displays this video signal sin only on a portion 11 of the display screen 1o. The mask signal generation means 16 generates a predetermined video signal (mask video signal) SI from the video signal corresponding to the edge portion of the screen thus displayed. For example, the video signal corresponding to the edge part can be the first scanning line (not necessarily one, but may be several) or the last scanning line (similarly).
The mask video signal Si can be a video signal standardized by the average brightness of these scanning line signals.

The video output means 14 is the other part 12 of the display screen 1o.
This mask video signal S□ is output to (the part where the video signal 8111 is not displayed). That is, on the display screen 10, a video signal 8111 input to a portion 11 is output (as is or after some conversion processing has been performed), and a mask video signal SMK depending on the input video signal is output to the other portion 12. is output.

EXAMPLE 1 Hereinafter, embodiments of the present invention will be described with reference to the drawings. Figure 2 shows a CRT (and an output video signal processing circuit immediately before it), which is a display means, among display devices implementing the present invention.
FIG. 2 is a block diagram showing the configuration of a portion excluding . This display device receives a high-definition (HDTV) broadcast signal, converts it into an NTSC signal, and displays it on a CRT. At this time, the aspect ratio of the screen according to the HDTV system is 9:1.
Since the CRT screen is wider than the NTSC screen (3:4 aspect ratio), if you try to display the entire input video on a CRT screen, as shown in Figure 3, the input HD
The TV image will be displayed in the central portion 51. Therefore, margin areas 50 and 5 are placed above and below this video output area 51.
2 occurs. The circuit shown in FIG. 2 is a circuit for generating a video signal (a combination of the center portion 51 and upper and lower margin portions 50° 52) to be output to the entire CRT at this time.

The input HDTV signal is first digitized by the A/D conversion circuit 20. The digitized HDTV video data is sequentially stored in the N1 line memory 22. The digital video data once stored in this memory 22 is
The signal is extracted at a timing delayed by N1 NTSC horizontal scanning period from the time the TV signal is input, and sent to the scanning line/time axis converter 30 via the delay adjustment circuit 24, gate 26, and adder 28. The operation of the delay adjustment circuit 24 will be described later.

On the other hand, digitized HDTV video data is gate 3
The signal is also input to the mask portion brightness signal generation circuit 36 via the signal line 8. Here, as shown in Figure 3, the first 1 field of video data (in the NTSC system) is
Video data DF corresponding to the main scanning line 53 and the last 1
Using video data DL corresponding to the main scanning line 54,
Upper mask image data Drlu and lower mask image data 7. generate. To explain in detail, first, the average brightness is calculated from the video data corresponding to the first one scanning line 53 (in this case, one upper and lower line is used, but of course it is possible to calculate the average brightness of several lines each) ). Then, achromatic color video data having this average luminance value is generated, and upper mask video data D is generated. It is set as U. The lower mask image data I) IL is exactly the same, and is achromatic image data having the average luminance of the image data corresponding to the last one scanning line 54 of one field.

The upper mask image data D0 and the lower mask image data I)nt generated in this way are input to the scanning line/time axis converter 30 via the gate 34.

In the scanning line/time axis conversion unit 30, N1 line memory 2
2 or the mask portion brightness signal generation circuit 36, the HDTV format digital video data is input from either the NTSC
The data is rearranged to suit the system and sent to the D/A converter 32. The D/A converter 32 converts this video data into a normal NTS
It is converted into a C format analog video signal and output to a display circuit. The rest is the same as a conventional NTSC television receiver.

Next, the timing of processing these video signals will be explained. The opening and closing of each gate 26, 34, 38 in this circuit is all controlled by a timing signal generated by a clock/timing generation circuit 40. First, the gate 38 between the A/D converter 20 and the mask brightness signal generation circuit 36 is connected to the oven (the gate 38 is connected to the oven for only one horizontal scanning period at the beginning and end of each field, counting the horizontal scanning period of the NTSC system.
(open), and closed (closed) during other periods. Therefore, as described above, in the mask portion brightness signal generation circuit 36, the (upper and lower) mask image has the average brightness of only the first scanning line 53 and the last scanning line 54. Data is generated. Note that it takes a certain amount of time to calculate the average brightness in the mask portion brightness signal generation circuit 36, and the output of the mask video data is delayed, so the delay adjustment circuit 24 delays the video data taken out from the N1 line memory by that time.

The gate 26 between the N1 line memory 22 and the scanning line/time axis converter 30 is closed only for the first N1 period and the last N2 period (counted in the horizontal scanning period of the NTSC system). , during other periods it will be an oven. Further, the gate 34 between the mask portion luminance signal generation circuit 36 and the scanning line/time axis conversion section 30 opens and closes in a reciprocal manner. That is, the gate 34 is an oven for the first N1 period and the last N2 period, and is closed for the other periods.

Therefore, on the CRT screen, as shown in FIG. 3, a portion 50 corresponding to the first N1 scanning lines at the top has a gray color having the average brightness of the first scanning line 53 of the image portion 51 immediately after it. A screen is displayed, with an HDTV broadcast image displayed in the center 51 and a lower part 5 corresponding to N2 scanning lines.
2, a gray screen is displayed having the average brightness of the last scan line 54 of the video portion 51 (which does not necessarily match the brightness of the upper part 50). This prevents the degree of deterioration (burning) of the CRT phosphor screen from being different between the upper and lower portions 50 and 52 and the center portion 51 even if H and DTV converted images are displayed for a long time.

Note that if the brightness of the input video signal changes rapidly, it may be difficult to see if the brightness of the upper and lower mask images also changes accordingly. Therefore, an integrating circuit is used to generate the mask part brightness signal in order to slow down the change in brightness over time. Provided in the circuit 36,
You may try to make the change gradual. Further, for the purpose of the present invention, the video signal of the mask portion does not need to be limited to gray as long as it has the average luminance as described above, and may be a calm color such as blue.

As explained above, according to the present invention, a mask video signal dependent on the input video signal is output to a portion of the display screen where the input video signal is not displayed. Therefore, by making the mask part a one-color image having the same luminance as the average brightness of the edge part of the input image, the degree of deterioration between the two sections of the display means (the input image display part and the mask image display part) can be reduced. are almost the same, and even if a video is output using the entire screen later, the boundary will not be noticeable. Note that this kind of screen deterioration is not limited to CRT fluorescent screens, but can also occur in other display systems, such as LED element deterioration, so the present invention is effective in such cases as well. has.

FIG. 1 is a diagram corresponding to the claims of the present invention, FIG. 2 is a block diagram of the signal conversion and screen configuration portions of a display device embodying the present invention, and FIG. 3 is a diagram showing the configuration of a CRT screen according to this embodiment. The explanatory diagram, FIG. 4, is a configuration diagram of a conventional CRT screen.

Claims (4)

[Claims] (1) A display device that receives a video signal from the outside and displays it on a display screen, comprising: mask signal generation means that generates a predetermined mask video signal from a signal corresponding to the edge of the screen in the video signal; A display device comprising: video output means for displaying the video signal on only a part of the display screen and displaying the mask video signal on the other part of the display screen. (2) The display according to claim 1, wherein the external video signal is a high-definition video signal, and the video output means converts the high-definition video signal into an NTSC video signal and displays it on the display screen. Device. (3) The mask signal generation means uses a video signal standardized by the average luminance of the video signal of the first scanning line among the video signals of one field of the high-definition system as an upper mask signal, and uses the video signal of the last scanning line as an upper mask signal. A video signal standardized by the average brightness of the signal is generated as a lower mask signal, and the video output means outputs the upper mask signal to the top of the display screen.
3. The display device according to claim 2, wherein the input video signal is output to the center of the display screen and the lower mask signal is output to the lower part of the display screen. (4) The display device according to claim 3, wherein the mask signal generation means generates the upper and lower mask signals using a luminance obtained by averaging the average luminance of the video signal of the first and last scanning lines for a plurality of fields.