JPH07322181A - Gamma correction circuit - Google Patents

Abstract

PURPOSE:To perform a proper gamma correction for the display video of each display in a multi-screen display device projecting single video or plural different video. CONSTITUTION:This circuit is composed of an individual gamma correction part 1 performing each required gamma correction for the video signal for every display, a whole gamma correction part 2 uniformly performing the gamma correction for the whole of the video signal, a multiprocessor processing part 3 outputting the discrimination signal corresponding to the whole constitution of the screen such as single video or plural different video, etc., a discrimination part 4 discriminating what signal source the video signal projected on each display belongs to based on the discrimination signal from the multiprocessor processing part 3, a memory part 5 storing proper gamma correction data corresponding to every video signal source and a control part 6 controlling the individual gamma correction part 1 and the whole gamma correction part 2 so as to perform each required gamma correction based on the discrimination result by the discrimination part 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gamma correction circuit, and more specifically, it is provided with a plurality of display elements such as PDP (plasma display panel) so as to display a single image or a plurality of different images. The present invention relates to a gamma correction circuit for appropriately performing gamma correction on a display image on each display in a multi-screen display device.

[0002]

2. Description of the Related Art A plurality of independent display elements such as PDP are provided to form one large screen, and a single image is displayed on this screen, or images of different signal sources are displayed for each individual display. In such a multi-screen display device, conventionally, gamma correction for a display image has been performed for all screens regardless of whether the screen configuration is a single image or a plurality of images. Therefore, for example, when multi-displaying a video signal having a personal computer as a signal source and a video signal having a television tuner as a signal source, the gamma correction required for each video signal is different, and a common gamma correction is applied to them. If so, at least one of the images is not properly gamma-corrected. Therefore, the original image will not be displayed correctly. The conventional multi-screen display has such a drawback.

[0003]

SUMMARY OF THE INVENTION The present invention is intended to improve the above-mentioned drawbacks in the conventional multi-screen display, and provides a gamma correction circuit for performing an appropriate gamma correction for each image of the multi-screen. The purpose is to provide.

[0004]

SUMMARY OF THE INVENTION The present invention is a multi-screen display device that is composed of a plurality of independent displays and displays a single image or a plurality of different images, and requires a video signal for each individual display. An individual gamma correction unit that performs the gamma correction of, and an entire gamma correction unit that uniformly performs the required gamma correction for the entire video signal,
A multi-processor processing unit that outputs an identification signal corresponding to the configuration of the entire screen, such as a single image or a plurality of different images,
Based on the identification signal from the multiprocessor processing unit,
A discriminating unit that discriminates what kind of signal source the video signal displayed on each display is, and a memory unit that stores the proper gamma correction data corresponding to each video signal source,
The present invention provides a gamma correction circuit including a control unit that controls the individual gamma correction unit and the overall gamma correction unit based on the result of the determination by the determination unit.

[0005]

The multiprocessor processing unit outputs an identification signal for identifying each signal source if the screen is a single image screen, a multiscreen, or if the screen is a multiscreen. The discriminating unit discriminates, via the control unit, whether the screen configuration is a single video screen or a multi-screen, including the video signal source, from the identification signal. On the other hand, in the memory section, the signal source of the input video (PC, TV tuner,
Alternatively, the appropriate gamma correction data for each laser disk or the like) is stored. The control unit determines the determination result by the determination unit,
Also, based on the gamma correction data for each projected image signal source read from the memory unit, the individual gamma correction unit and the overall gamma correction unit are controlled to perform the required gamma correction for the video signal for each display. Let it be done.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A gamma correction circuit according to the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of an essential part showing an embodiment of a gamma correction circuit according to the present invention, and FIG. 2 is a view showing an example of a projected state of a screen composed of nine displays.
(A) is an example of enlarging and displaying a single image, and (B) is 6
It is an example of a multi-screen display consisting of types of images. In FIG. 1, S1 is an input video signal composed of a single video or a plurality of different videos, 1 is an individual gamma correction unit that performs individual gamma (γ) correction on the video signal of each display,
Reference numeral 2 is an entire gamma correction unit that performs uniform gamma correction on the entire video signal, and 3 is a screen with a single video screen, or multiple different video screens. A multiprocessor processing unit 4 which outputs an identification signal used for identifying a signal source includes a video signal source including whether the screen configuration is a single video screen or a multiscreen from the identification signal from the multiprocessor processing unit. Discriminating unit 5 discriminates the appropriate gamma correction data for each video signal source, 6 discriminates the discrimination result by the discriminating unit 4, and the video signal source for each image signal read out from the memory unit. The control unit controls the individual gamma correction unit and the entire gamma correction unit based on the gamma correction data to perform the required gamma correction on the video signal of each individual display.

It is arbitrary how many independent display elements (PDP, etc.) the multi-screen display device is composed of.
In this embodiment, as shown in FIG. 2, it is assumed to be composed of nine display elements, and independent displays are represented by D1 to D9 as shown in the drawing. The operation of the present invention will be described below based on the configuration of FIG. How the nine displays shown in FIG. 2 are used (display mode) is associated with the identification signal output from the multiprocessor processing unit 3. The same figure (A) shows a case where a single image is displayed on nine displays, which is an enlarged screen, and the same (B) shows D1 and
Enlarge one image with D2, D4, and D5
3, D6 ~ D9) is the case of multi-screen display that displays separate images. Of course, there are various display modes other than the above.

Here, the signal source of the video signal S1 is NT
In addition to SC type general video (TV broadcasting, VTR, laser disk, etc.), there is a personal computer. The signal of the former general image is subjected to a predetermined gamma correction on the signal itself, but the image of a personal computer is generally not subjected to gamma correction. The present invention performs gamma correction originally necessary on the receiving device side for such different signals. The multiprocessor processing unit 3 generates and outputs an identification signal S2 indicating the display state of D1 to D9. This identification signal can be generated, for example, by counting horizontal pulses (HD) in one field period (VD) as one method, or by another method.
Although the sampling clock is changed depending on the signal source, it is possible to identify the signal source by receiving the information at the time when the sampling clock is changed and to generate a signal corresponding to the signal source. For example, as the identification signal in the case of the display mode of FIG.
D1, D2, D4 and D5 are signals indicating that the video signals from the same signal source are enlarged and displayed, and D3, D6 to D9 are signals that respectively display different images. The discrimination unit 4 discriminates from the same identification signal S2 from the multiprocessor processing unit 3 whether the display mode is an enlarged display of a single image (FIG. 2A) or a multi-screen display (Same B etc.) including the image signal source. To do. By this determination, the video content displayed on each of the displays D1 to D9 is found.

On the other hand, the memory section 5 stores required gamma correction data for each video signal source. The control unit 6 reads out the gamma correction data relating to the image signal to be projected, which is discriminated by the discriminating unit 4, from the memory unit 5, and performs a required gamma correction on the image signal for each display based on the data. To do. This gamma correction is performed by an individual gamma correction unit 1 that performs correction for each display and an overall gamma correction unit 2 that uniformly corrects all displayed images. In this case, the correction mode for each video is basically divided into the following three types depending on the display mode and the video content (signal source). (1) When correction is performed by both the individual gamma correction unit 1 and the overall gamma correction unit 2 (2) When correction is performed only by the individual gamma correction unit 1 and the entire gamma correction unit 2 is not corrected and the through is performed ( 3) In the case where the individual gamma correction unit 1 does not perform the correction and the through is performed, and the entire gamma correction unit 2 performs the correction only.

As an example, the following three display modes will be described with reference to FIG. (1) As shown in FIG. 2 (A), nine displays (D1 ~
In the case of enlarging and displaying one image with D9) In this case, the individual gamma correction unit 1 does not perform the correction and the through is performed, and the common gamma correction unit 2 performs the common correction (γ
Perform 1). (2) As shown in Fig. 2 (B), D1, D2, D4, and D5 display enlarged PC images, D3 TV broadcasting 1ch, D6 PC, D7 TV broadcasting 4ch, D8 PC, D9 down converter In this case, D1, D2, D4 and D5 perform common correction (γ1) by the entire gamma correction unit 2, and other individual gamma correction (γ2) by the individual gamma correction unit 1. ~ Γ
6) is performed, and the entire gamma correction unit 2 is set to “through”.

(3) In the above (2), during the enlarged display of the personal computer image on D1, D2, D4 and D5, the image from a handy camera or the like is further displayed on a sub-screen (so-called PI).
In the case of displaying as P) In this case, in addition to the correction in (2), the individual gamma correction unit 1 corrects the child screen portion. The control signals S3 and S4 from the control unit 6 are used to switch whether each gamma correction unit should be corrected or through. The signal gamma-corrected in this way is the video output S5, which is the display D1.
~ It is displayed as a single image or multiple images by D9.

[0012]

As described above, according to the present invention, in a multi-screen display device which displays a single image or multiple images on a plurality of independent displays, an appropriate gamma correction can be performed for each image. it can. Therefore, the image quality is not deteriorated even when the image from the personal computer or the image such as the television broadcast signal is displayed at the same time. From the above, the present invention contributes to improving the performance of a multi-screen display device.

[Brief description of drawings]

FIG. 1 is a block diagram of essential parts showing an embodiment of a gamma correction circuit according to the present invention.

2A and 2B are explanatory diagrams of display modes, in which FIG. 2A is an enlarged display example of a single image, and FIG. 2B is a display example of multiple images.

[Explanation of symbols]

 S1 Input video signal 1 Individual gamma correction unit 2 Overall gamma correction unit 3 Multiprocessor processing unit 4 Discrimination unit 5 Memory unit 6 Control unit

Claims (3)

[Claims] 1. In a multi-screen display device configured by a plurality of independent displays and displaying a single image or a plurality of different images, an individual gamma correction for performing a required gamma correction on an image signal of each display. Unit, an entire gamma correction unit that uniformly performs a required gamma correction on the entire video signal, and a multiprocessor processing unit that outputs an identification signal corresponding to the entire screen configuration, such as a single image or a plurality of different images, Based on the identification signal from the multiprocessor processing unit, a determination unit that determines which signal source the video signal displayed on each display is, and the appropriate gamma correction data is stored for each video signal source. The memory unit and the individual gamma correction unit and the overall gamma correction unit based on the discrimination result by the discrimination unit. A gamma correction circuit configured with a control unit that performs control for performing necessary gamma correction. 2. The control unit controls the individual gamma correction unit so that the correction by the individual gamma correction unit is stopped and the signal is passed through based on the identification signal from the multiprocessor processing unit. The gamma correction circuit according to claim 1, wherein: 3. The control unit controls the overall gamma correction unit so that the correction by the overall gamma correction unit is stopped and the signal is passed through based on the identification signal from the multiprocessor processing unit. The gamma correction circuit according to claim 1, wherein: