KR102205860B1 - Calibration method for providing interactive realistic media - Google Patents

Abstract

Disclosed is a calibration method for providing an interactive realistic media. The present calibration method for providing the interactive realistic media includes: a step of transmitting, by a main display, basic color coordinate values; a step of receiving, by a peripheral display, the basic color coordinate values from the main display, and setting a color set of the peripheral display according to the basic color coordinate values; a step of receiving, by the main display, corrected color coordinate values and transmitting the corrected color coordinate values to the peripheral display; and a step of receiving, by the peripheral display, the corrected color coordinate values from the main display, and changing the color set of the peripheral display according to the corrected color coordinate values. Accordingly, the problem for which image quality or color difference between multiple displays occurs even after setting the same color set value is solved, thereby minimizing heterogeneity when multiple displays provide one interactive realistic media.

Description

The calibration method for providing interactive realistic media {Calibration method for providing interactive realistic media}

The present invention relates to a calibration method for providing interactive sensory media, and more particularly, when interactive sensory media is provided on a large screen through a plurality of displays, the relative color coordinate values of each display are changed by changing the absolute color coordinate value of each display. The present invention relates to a calibration method for providing interactive sensory media to minimize interference due to heterogeneity in viewing interactive sensory media by making them the same.

Multi-walls are used for various purposes, such as outdoor advertisements and contents that are given immersion and realism through a large screen. In such a multi-wall, a plurality of displays are integrated with each other, and one content is displayed on a single display through the integrated full screen, but is provided on a large screen.

Since the multi-wall is composed of a plurality of displays as described above, color deviation may occur between displays.

Of course, there may be parts that can be corrected using the color correction function built into the display, but because the physical characteristics between displays cannot be perfectly matched, even if the color characteristics are matched with the same numerical value, the color deviation is mutual It has an essential problem of having to make a difference.

As the human eye ages, the phenomenon in which the color deviation of each display constituting the multi-wall increases as time passes, and this color deviation is caused by users who enjoy a single content through a large screen. From the standpoint, it brings inconvenience that hinders the sense of immersion.

Korean Patent Laid-Open Patent No. 10-2006-0010268 (A method and apparatus for correcting image quality of an image display device)

The present invention was conceived to solve the above problems, and an object of the present invention is to correct the relative difference that may occur even when the absolute color coordinate values of the displays constituting the multi-wall are matched, thereby reducing the sense of heterogeneity in viewing interactive sensational media The objective is to provide a calibration method for providing interactive sensational media that minimizes interference.

In order to achieve the above object, a calibration method for providing interactive sensory media according to an embodiment of the present invention includes: transmitting, by a main display, a basic color coordinate value; Receiving, by a peripheral display, the basic color coordinate value from the main display and setting a color setting of the peripheral display according to the basic color coordinate value; Receiving, by the main display, a correction color coordinate value and transmitting it to the peripheral display; And changing, by the peripheral display, a color setting of the peripheral display according to the corrected color coordinate value by receiving the corrected color coordinate value from the main display.

Here, when there are a plurality of peripheral displays, the corrected color coordinate value is calculated for each peripheral display and input to the main display, and the main display individually transmits the corrected color coordinate value for each peripheral display. I can.

In addition, the main display and the peripheral display may constitute one multi-wall.

In addition, when a command to configure a multi-wall together with the surrounding display is input, the main display may transmit the basic color coordinate value to the surrounding display after the command is input.

And, the step of receiving, by the server, the photographed image for the multi-wall from the camera device; further comprising, the main display, when receiving the correction color coordinate value from the server after the photographed image is received from the server , May transmit the correction color coordinate value to the peripheral display.

In addition, the server may individually calculate the corrected color coordinate value for each peripheral display, and transmit the calculated corrected color coordinate value to the main display.

And determining, by the server, one of the displays constituting the multi-wall as the main display after receiving the photographed image for the multi-wall from the camera device; And transmitting, by the server, a command to set the color setting according to the basic color coordinate value of the main display to the determined main display; further comprising, the main display transmitting the basic color coordinate value. When the main display receives a command to set a color setting according to the basic color coordinate value of the main display from the server, it determines that the command is a main display determination command and transmits the basic color coordinate value to the surrounding display. I can.

In addition, the server divides the captured image received from the camera device, calculates a color coordinate value for each divided area of the captured image, and calculates the color coordinate value based on the difference between the calculated color coordinate value and the basic color coordinate value. Corrected color coordinate values can be calculated.

In addition, the corrected color coordinate value according to the difference between the calculated color coordinate value and the basic color coordinate value may be stored and provided as a lookup table in the server.

Further, the determination of the main display may be changed each time the camera device photographs the multiwall.

Accordingly, it is possible to solve the problem that differences in quality or color may occur between multiple displays even after setting the same color setting value, thereby minimizing the sense of heterogeneity in the case where multiple displays provide one interactive sensory media. do.

1 is a diagram illustrating a system for matching color characteristics between displays in a multiwall for providing interactive sensory media.
2 is a flowchart illustrating a calibration method for providing interactive sensory media according to an embodiment of the present invention.
3 is a flowchart illustrating a calibration method for providing interactive sensory media according to another embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. The embodiments introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly describe the present invention, parts not related to the description will be omitted from the drawings.

1 is a diagram illustrating a system for matching color characteristics between displays in a multiwall for providing interactive sensory media.

The system according to the present embodiment includes a multi-wall 100, a camera device 200 and a server 300.

The multiwall 100 is provided for the purpose of providing one interactive sensory media as a whole by arranging a plurality of displays in a plurality of columns and a plurality of rows. Accordingly, users can view more realistic and realistic images on a large screen through the multiwall 100 in which a plurality of displays are integrated.

In order to provide a sense of immersion in the provided sensory media, the multi-wall 100 is created by combining displays of the same manufacturer and the production timing not significantly different.

The reason for configuring the multi-wall 100 by combining the same or similar displays as described above is to provide a sense of immersion in viewing a single image with a sense of unity as a whole by minimizing color deviation.

However, even if the multiwall 100 is composed of similar products, the physical characteristics between the displays cannot be perfectly matched with each other, so even if the color characteristics are set to match each other with the same numerical value, color deviation occurs. You have an essential problem that you have to do.

In this case, the administrator may adjust the setting values of the displays constituting the multiwall 100 one by one to have more improved color deviation.

However, since the multi-wall 100 is generally used outdoors for the purpose of providing a large screen, there is a limit to accessing the multi-wall 100 and changing the setting value whenever color deviation occurs. As the display ages over time, the problem accelerates.

To this end, in the calibration method for providing interactive sensory media according to the present embodiment, the camera device 200 captures a screen displayed on the multiwall 100, and a server based on the captured image captured by the camera device 200 By calculating and providing a corrected color coordinate value to be calibrated for each display at 300, it is possible to automatically match color characteristics between displays without the need for an administrator to manually operate.

Meanwhile, it has been described above that the multi-wall 100 is composed of a plurality of displays. The multi-wall 100 may be divided into a main display 110 and a sub-display 120, which are a reference for calibration.

In addition, there may be cases where the main display 110 is arbitrarily designated by an administrator with reference to a case where the main display 110 is located among a plurality of displays constituting the multi-wall 100 or the production date is closest to the average, There may be a case where the server 300 or the multi-wall 100 decides itself by excluding human intervention.

Hereinafter, the former will be described with reference to FIG. 2, and the latter will be described with reference to FIG. 3.

2 is a flowchart illustrating a calibration method for providing interactive sensory media according to an embodiment of the present invention.

First, the main display 110 designated by the administrator transmits a basic color coordinate value of its own to the sub-display 120 (S110). If the multi-wall 100 is not composed of two displays, but is composed of more than two such as four or nine, the main display 110 uses the basic color coordinate values of all the sub displays 120 ), respectively.

Here, the basic color coordinate value is a color coordinate value currently applied to the main display 110, for example, CIE (0.68, 0.32), which is the darkest and pure red coordinate among the ranges conforming to the NTSC (National television system committee) standard. It may be the coordinates of CIE (0.3, 0.5), which is the color of a specific point in an arbitrary triangle consisting of CIE (0.21, 0.72), which is the coordinates of dark and pure green, and CIE (0.14, 0.80), which is the darkest and purest blue.

These basic color coordinate values are color coordinate values currently applied to the main display 110, so even if they are different from the above example, the main display 110 performs absolute equalization of the basic color coordinate values, and then calibration according to the relative difference is performed. In order to do so, the basic color coordinate value as described above is transmitted to the sub-display 120.

In this way, after the basic color coordinate value is transmitted from the main display 110 to the sub-display 120, the sub-display 120 sets the color setting based on the received basic color coordinate value (S120).

In this way, after the main display 110 and the sub-display 120 set color settings according to the basic color coordinate values having the same absolute value, the camera device 200 is configured to display a basic color coordinate value having the same absolute value. The wall 100 is photographed and transmitted to the server 300.

After receiving the captured image from the camera device 200 (S130), the server 300 calculates a corrected color coordinate value based on the received captured image (S140).

To this end, the server 300 divides the captured image received from the camera device 200 and calculates a color coordinate value for each divided area.

That is, the captured image received by the server 300 is a captured image of the entire multiwall 100, and such a captured image can be divided into a screen area provided by each display device.

These photographed images are images photographed with color settings set according to the basic color coordinate values, but as described above, the physical characteristics of each display cannot be perfectly matched, so the entire image of the multiwall 100 It is bound to have different color characteristics.

The difference in color characteristics is analyzed by the server 300 to calculate a difference value for a relative color coordinate value, and the server 300 calculates a corrected color coordinate value based on the difference value.

For example, if the area displayed by the main display 110 is analyzed to have the coordinates of CIE (0.3, 0.5) and the area displayed by the sub-display 120 is analyzed to have the coordinates of CIE (0.4, 0.6) , (0.1, 0.1), so the server 300 displays the screen with the default color coordinate value of the current CIE (0.3, 0.5) in the server 300, but the CIE (0.2, 0.4) To have the color coordinate value of

Of course, subtracting the corrected color coordinate value by 0.1 because the basic color coordinate value set by the main display 110 and the color coordinate value calculated by the server 400 numerically shows a difference of 0.1 is an example for convenience of explanation. It would be just the enemy.

Accordingly, data on the basic color coordinate values set by the main display 110, data on the color coordinate values calculated by the server 400, and the basic color coordinate values set by the main display 110 and the server 400 ), based on the data on the difference in color coordinate values calculated by the main display 110, what is the basic color coordinate value set by the main display 110, what the color coordinate value calculated by the server 400, and the main According to what is the difference between the basic color coordinate value set by the display 110 and the color coordinate value calculated by the server 400, a lookup table in the server 300 is used. It may be prepared and stored in advance.

In this way, the corrected color coordinate value calculated based on the lookup table in the server 300 is transferred to the main display 110 (S150). As described above, when there are two or more sub-displays 120, each sub-display 120 ), the corrected color coordinate values calculated differently from each other will be delivered together with information on each sub-display 120.

The main display 110 transmits the corrected color coordinate value received from the server 300 to the sub display 120 (S160), and in particular, based on the information on the sub display 120 received from the server 300 The corrected color coordinate values matched with the information are transmitted to each sub-display 120.

Thereafter, the sub-display 120 changes the color setting according to the individually received correction color coordinate values to suit itself (S170).

Accordingly, each display constituting the multiwall 100 is unified with an absolute color coordinate value, generates a reference for correction, and then corrects the color coordinate value based on the data received by the server 300 so that relative color characteristics are mutually Matching and color balance can be achieved.

3 is a flowchart illustrating a calibration method for providing interactive sensory media according to another embodiment of the present invention.

As described above, in this embodiment, the server 300 or the multi-wall 100 determines the main display 110 by itself without human intervention.

First, in a state in which the multi-wall 100 is configured, the camera device 200 photographs the multi-wall 100 and transmits the captured image to the server 300, and the server 300 takes a picture from the camera device 200. The image is received (S210).

When receiving the captured image as described above, a screen according to a unified color coordinate value may be displayed on the captured image for each display, and the screen may be displayed in a state independent of the color coordinate value.

The server 300 determines the main display 110 based on the received captured image (S220).

In this way, when the server 300 determines the main display 110, it excludes a display with a large sense of heterogeneity with a plurality of displays, and prioritizes the display located in the center so that communication with other displays is as smooth as possible. The main display 110 may be determined according to an algorithm.

In addition, the server 300 may already have specification information, manufacturing date information, serial number information, etc. of the displays constituting the multiwall 100. In this case, the most recently produced display is the main display 110 You might decide to

When the main display 110 is determined as described above, a color setting setting command is transmitted to the corresponding main display 110 based on the previously stored serial number information (S230).

Accordingly, the display that has received the color setting setting command regards it as being designated as the main display 110 (S240), and transmits a basic color coordinate value to the sub-display 120 (S250), and the sub-display 120 Color setting is set according to the received basic color coordinate value (S260).

These steps S250 and S260 may be said to be the same as steps S110 and S120 described above.

When the color setting setting is completed in this way, the server 300 re-receives the captured image in a state in which the color setting has been completed from the camera device 200 (S270), and by performing the same steps as in steps S140 to S170, The color setting of the sub display 120 can be changed.

In this way, the relative color characteristics between the displays constituting the multi-wall 100 can be matched with each other and the color balance can be matched, as well as the multi-wall according to the automated designation method even if the administrator does not designate the main display 110 separately. It is possible to match color characteristics between displays constituting 100.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, specific embodiments for effectively explaining the technical idea of the present invention are mainly illustrated and described. Therefore, the present invention is not limited only to the above-described embodiments, and any person of ordinary skill in the art to which the present invention belongs can perform various changes without departing from the gist of the technical idea of the invention described in the following claims. You can do it. In addition, the scope of the present invention is indicated by the claims described later rather than the detailed description above. In addition, all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention.

100: multiwall 110: main display
120: peripheral display 200: camera device
300: server

Claims (10)

In the calibration method for providing interactive realistic media,
Transmitting, by the main display, a basic color coordinate value;
Receiving, by a peripheral display, the basic color coordinate value from the main display and setting a color setting of the peripheral display according to the basic color coordinate value;
Receiving, by the main display, a correction color coordinate value and transmitting it to the peripheral display; And
Including, by the peripheral display, receiving the corrected color coordinate value from the main display and changing a color setting of the peripheral display according to the corrected color coordinate value; and
When there are a plurality of peripheral displays, the corrected color coordinate value is calculated for each peripheral display and input to the main display,
The main display individually transmits the corrected color coordinate value for each peripheral display for each peripheral display,
The main display and the peripheral display,
It constitutes one multiwall,
The main display,
When a command to configure a multi-wall with the surrounding display is input, the basic color coordinate value is transmitted to the surrounding display after the command is input,
The calibration method for providing the interactive sensory media,
Receiving, by the server, the photographed image for the multi-wall from the camera device; further comprising,
The main display,
The server receives the corrected color coordinate value from the server after receiving the captured image for the multi-wall from the camera device, and when receiving the corrected color coordinate value from the server, the corrected color coordinate value is transmitted to the peripheral display. And
The server,
The correction color coordinate value is individually calculated for each of the peripheral displays, and the calculated correction color coordinate value is transmitted to the main display,
The calibration method for providing the interactive sensory media,
Determining, by the server, one of the displays constituting the multi-wall as the main display after receiving the photographed image for the multi-wall from the camera device; And
Transmitting, by the server, a command to set the color setting according to the basic color coordinate value of the main display to the determined main display; and
The step of transmitting, by the main display, the basic color coordinate value,
When the main display receives a command to set a color setting according to a basic color coordinate value of the main display from the server, it determines that the command is a main display determination command and transmits the basic color coordinate value to the peripheral display,
The determination of the main display is determined according to whether a display has been most recently produced based on serial number information of the displays obtained by the camera device. delete delete delete delete delete delete The method of claim 1,
The server divides the captured image received from the camera device, and calculates a color coordinate value for each divided area in the captured image,
And calculating the corrected color coordinate value based on a difference between the calculated color coordinate value and the basic color coordinate value. The method of claim 8,
The calibration method for providing interactive sensory media, wherein the corrected color coordinate value according to a difference between the calculated color coordinate value and the basic color coordinate value is stored and provided as a lookup table in the server. delete

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