JP5424366B2 - Display control apparatus and display control method - Google Patents

Description

  The present invention relates to a display control device and a display control method.

In recent years, multiple self-luminous displays (display devices) such as CRTs (Cathode Ray Tubes) and LCDs (Liquid Crystal Displays) with backlights are arranged in a matrix, and multiple displays are operated in cooperation with each other. Display is widespread. Using this multi-display, displaying a large screen image, displaying a plurality of different image data at once, and the like are widely performed.
Multi-displays are also used in the medical field, and a technique for correcting a luminance difference between displays in order to display a uniform image is known (Patent Document 1).

  By the way, in the multi-display, in order to display an image corresponding to the arrangement position on each display, it is necessary to set position information (identification information setting) for identifying the position where each display is arranged in the multi-display. The position information is set individually for each display through an OSD (On Screen Display) by an operation of a multi-display user or administrator. The setting of the position information is a work that takes a lot of time when the number of displays constituting the multi-display is large, and it is desired to facilitate the setting.

  Further, when configuring a multi-display, the same type of display is often used, and in this case, a remote controller for operating the display is common. For this reason, before the remote controller ID (IDentifier) is set, if the display is operated by the remote controller, all the displays respond, and therefore it is not possible to set each display. On the other hand, if the ID setting of the remote control is performed, only the display associated with the ID of the remote control can be operated. Therefore, there is a problem that the position information cannot be set efficiently even if the remote control is used. .

  With respect to such a problem, there is a technique for setting the position information by detecting the arrangement position of each display by connecting to all the displays constituting the multi-display with an adjacent display (Patent Document 2). ).

JP 2004-242143 A JP 05-249932 A

  However, in the multi-display described in the above-mentioned Patent Document 2, it is necessary to connect adjacent displays in the up, down, left, and right directions, so that it takes time to connect, and as a result, it takes time to set position information. There is a problem that it ends up.

  The present invention has been made in view of the above problems, and in the setting of position information indicating which position of each display in the multi-display is arranged in the multi-display, the display control can easily set the position information. An apparatus and a control method are provided.

In order to solve the above problems, a display control device according to the present invention includes a rectangular display unit, an outer frame surrounding the outer periphery of the display unit, and a short side center of the outer frame in contact with the short side of the display unit. And a plurality of display devices arranged in a matrix having the illuminance sensors arranged at any one of the ranges except for the respective illuminance sensors. A basic position detection unit that identifies a display device arranged at a predetermined basic position among the plurality of display devices, and a display device that is identified by the basic position detection unit And a relative position detector that detects in which position of the matrix the plurality of display devices are based on illuminance values output from the illuminance sensors of the plurality of display devices. And wherein the door.
The display control method of the present invention includes any of a rectangular display unit, an outer frame surrounding the outer periphery of the display unit, and a range of the outer frame that is in contact with the short side of the display unit and excluding the center of the short side. Illuminance detected by each of the illuminance sensors, with each of the display units sequentially turned on one by one with respect to a plurality of display devices arranged in a matrix having an illuminance sensor arranged in one place. Depending on the value, the process of identifying a display device arranged at a predetermined basic position among the plurality of display devices, and lighting the display device identified by the basic position detection unit, the plurality of display devices And a step of detecting at which position of the matrix the plurality of display devices are arranged based on an illuminance value output from the illuminance sensor.

  According to the present invention, when a multi-display is configured using a plurality of display devices, the display devices are arranged at any one location other than the midpoint on the short side of the periphery of the display unit included in each display device. By using the illuminance sensor, the display devices can be turned on one by one in order, and the position where each display device is arranged can be detected based on the illuminance value output from the illuminance sensor. It can be performed.

1 is a schematic block diagram showing a configuration of a multi-display system 100 as an embodiment of the present invention. It is a figure which shows an example of the positional information in this embodiment. In this embodiment, it is the figure which showed the order | rank of the illuminance value detected when the basic position detection part 12 lights the display 2a. It is the figure which showed the frequency | count of detecting the 2nd highest illuminance value in each illuminance sensor 21a-21i when the displays 2a-2i are lighted in order in this embodiment. It is a figure which shows an example of the illumination intensity distribution information in this embodiment. In this embodiment, when the basic position detection part 12 lights the display of ID "1"-"9", it is the figure which showed ID of the display which detects the 1st-3rd illuminance value. It is the schematic diagram shown about the case of the multi-display of the size of 3 rows 4 columns while an illuminance sensor is arrange | positioned at the lower part of the right periphery of a bezel. It is the schematic diagram shown about the case of the multi-display of the size of 4 rows and 4 columns while an illuminance sensor is arrange | positioned in the lower part of the right periphery of a bezel. It is the schematic diagram shown about the case where the illumination intensity sensor is arrange | positioned at the upper part of the right side periphery of a bezel, and the size of 4 rows 4 columns size. It is the schematic diagram shown about the case of the multi-display of the size of 4 rows 4 columns while an illumination intensity sensor is arrange | positioned at the lower part of the left side periphery of a bezel. It is the schematic diagram shown about the case where the illumination intensity sensor is arrange | positioned at the upper part of the left side periphery of a bezel, and is a multi-display of the size of 4 rows 4 columns. FIG. 11 is a diagram showing a distribution of the number of times each display outputs the second highest illuminance value when the illuminance sensor is arranged at the right part of the upper peripheral edge of the bezel in a multi-display having a size of 4 rows and 4 columns. FIG. 11 is a diagram showing a distribution of the number of times each display outputs the second highest illuminance value when the illuminance sensor is arranged at the center of the right peripheral edge of the bezel in a multi-display having a size of 4 rows and 4 columns. It is the schematic diagram shown about the case where the illumination intensity sensor is arrange | positioned at the lower part of the short side right side periphery of a bezel, and the size of m rows n columns (mxn) size.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram showing a configuration of a multi-display system 100 as an embodiment of the present invention. In this embodiment, a case where one multi-display (display area) 20 is configured by arranging nine identical displays (display devices) in a matrix of 3 rows and 3 columns (3 × 3) will be described.

As illustrated, the multi-display system 100 includes a display control device 1, nine displays 2a to 2i constituting the multi-display 20, and serial cables 3a to 3i that connect the display control device 1 and the displays 2a to 2i. It has.
Each of the displays 2a to 2i includes a lower part of the right peripheral edge of a bezel (outer frame) provided on the peripheral edge so as to surround the outer periphery of the display part, and the same surface side as the display surface of the display part. Illuminance sensors 21a to 21i are arranged at the same position on the display. The illuminance sensors 21a to 21i output illuminance values according to the detected illuminance. In this embodiment, the illuminance sensors 21a to 21i are arranged at positions where the illuminance of the display on which the illuminance sensors 21a to 21i are arranged can be detected.

  The display control device 1 has a function of detecting the positions of the connected displays 2a to 2i in the multi-display 20, and includes a control unit 11, a basic position detection unit 12, a relative position detection unit 13, and A position information storage unit 14 and an illuminance distribution storage unit 15 are provided.

The position information storage unit 14 stores position information. FIG. 2 is a diagram illustrating an example of position information in the present embodiment. As shown in the figure, the position information includes the ID of each of the displays 2a to 2i connected to the display control device 1, the count value of the display, and arrangement information indicating the position of the display on the multi-display 20. Correspondingly stored. The count value is the number of times the illuminance sensors 21a to 21i provided in the respective displays 2a to 2i detect the second largest illuminance value among all the illuminance sensors 21a to 21i. The initial value of this count value is “0”. The arrangement information is information indicating the position where each display is arranged in the multi-display, and is represented by (row number, column number) when the upper left is the base point (1, 1).
As shown in FIG. 2, IDs “1” to “9” assigned to the displays 2a to 2i are stored, and count values and arrangement information are stored in association with the respective IDs. For example, a count value “3” and a position “(2, 1)” as arrangement information are stored in association with ID “6”.

The control unit 11 sequentially assigns an identifier (ID) that can be uniquely identified to each of the displays 2 a to 2 i connected to the display control device 1, and assigns each identifier of the connected displays 2 a to 2 i to the position information storage unit 14. Remember. Alternatively, the control unit 11 may display a message such as “Please set ID = 1” on the connected display, and store the ID on the display by a user operation.
In addition, when the control unit 11 stores the ID in the position information storage unit 14, the initial value of the count value is set to “0” and the information indicating the position is set to null. Moreover, the control part 11 starts the basic position detection part 12 after all the displays 2a-2i are connected.

The basic position detection unit 12 selects any one based on the IDs (“1” to “9”) assigned to the displays 2a to 2i, and sequentially turns on the displays 2a to 2i one by one. The illuminance values detected by the illuminance sensors 21a to 21i when the 2a to 2i are turned on are received. In addition, the basic position detection unit 12 sets the ID count value corresponding to the illuminance sensor that has detected the second largest illuminance value among the received illuminance values with respect to the position information stored in the position information storage unit 14. Update processing to increase “1” is performed.
FIG. 3 is a diagram showing the order of the illuminance values detected when the basic position detection unit 12 lights the display 2a in the present embodiment. As illustrated, the illuminance value detected by the illuminance sensor 21a is the largest, the illuminance value detected by the illuminance sensor 21f is the second largest, and the illuminance value detected by the illuminance sensor 21b is the third largest, The illuminance value detected by 21e is the fourth largest. That is, the illuminance value detected by each of the illuminance sensors 21a to 21i increases as the distance from the lit display to the illuminance sensor becomes shorter.

In addition, the basic position detection unit 12 detects a display arranged at a specific position by sequentially lighting any one of the displays 21a to 21i until the count value of any ID becomes 3. This is based on the characteristic that when the displays 2a to 2i are sequentially turned on one by one, the illuminance sensor of the display arranged at a specific position detects the second largest illuminance value three times. 12 detects a display arranged at a basic position which is a specific position.
Further, when the basic position detection unit 12 specifies the display arranged at the basic position, the basic position is associated with the ID of the display and stored in the position information storage unit 14 and the relative position detection unit 13 is activated. This basic position is one of the positions where the displays in the multi-display are arranged, and is a position uniquely determined according to the arrangement positions of the illuminance sensors 21a to 21i provided in the displays 21a to 21i.

  FIG. 4 is a diagram showing the number of times of detecting the second highest illuminance value in each of the illuminance sensors 21a to 21i when the displays 2a to 2i are sequentially turned on in the present embodiment. As shown in the figure, when the displays 2a to 2i are arranged in a 3 × 3 matrix, and the illuminance sensors 21a to 21i are arranged at the lower part of the right peripheral edge of the bezel, the illuminance sensors 21a to 21i are arranged in two rows and one column (position The illuminance sensor 21f of the display 2f arranged at the basic position (2, 1) detects the second largest illuminance value three times. That is, the display 2f having an illuminance sensor that detects the second largest illuminance value three times is disposed at the basic position of the position (2, 1).

  The relative position detection unit 13 lights one of the displays arranged at the basic position detected by the basic position detection unit 12 and displays a multi-display based on the illuminance distribution information stored in advance in the illuminance distribution storage unit 15. The position where each other display which comprises is arranged is specified.

  The illuminance distribution storage unit 15 stores illuminance distribution information in advance. This illuminance distribution information is associated with the order of the illuminance values detected by each illuminance sensor when a display located at a predetermined basic position is turned on and the arrangement information of each display in the multi-display. Information. This illuminance distribution information is information determined according to the distance from the basic position to each illuminance sensor. FIG. 5 is a diagram illustrating an example of illuminance distribution information in the present embodiment. As shown in the figure, when the display arranged at the position (2, 1) is turned on, the order of the illuminance values detected by the illuminance sensor of each display and the position (2, 1) as the arrangement information , (1, 1), (3, 1), ..., (3, 3) are associated with each other.

Next, the operation of the display control device 1 in this embodiment will be described.
In the display control device 1, the control unit 11 is arranged so that the displays 2a to 2i are 3 × 3 multi-displays as shown in FIG. 1 and are connected via the serial cables 3a to 3i. Commands for assigning IDs “1” to “9” to the displays 2 a to 2 i in the order of connection are output to store the IDs assigned to the displays 2 a to 2 i, and the assigned IDs are stored in the position information storage unit 14. Let And the control part 11 starts the basic position detection part 12, after all the displays 2a-2i are connected.

Next, the basic position detection unit 12 identifies each of the displays 2a to 2i based on the IDs “1” to “9” assigned by the control unit 11, thereby sequentially lighting any one of the displays 2a to 2i. The illuminance value is received from the displays 2a to 2i. Then, the basic position detection unit 12 increases the count value of the ID of the display having the second highest illuminance value among the received illuminance values by “1” until the next display is turned on.
FIG. 6 shows display IDs for detecting the first to third illuminance values when the basic position detection unit 12 sequentially turns on the displays of ID “1” to “9” one by one in this embodiment. FIG. When the basic position detection unit 12 lights each display in the order shown, the count value of ID “6” becomes 3 when the display 2 g of ID “7” is turned on.

The basic position detection unit 12 detects that the display 2f with ID “6” having a count value of 3 is arranged at the position (2, 1) which is the basic position, and indicates the position (2, 1). The information is stored in the position information storage unit 14 in association with the ID “6”. The position information after the basic position detection unit 12 stores the position (2, 1) in association with the ID “6” is in the state shown in FIG.
Then, the basic position detection unit 12 activates the relative position detection unit 13.

The relative position detection unit 13 is based on the fact that the display 2f assigned the ID “6” is arranged at the basic position (2, 1) and the illuminance distribution information stored in the illuminance distribution storage unit 15 in advance. Then, the positions where the other displays 2a to 2e and 2g to 2i are arranged are detected as follows.
First, the relative position detection unit 13 turns on the display 2f arranged at the basic position (2, 1), and receives illuminance values from the illuminance sensors 21a to 21i. The relative position detection unit 13 stores “6, 1, 7, 5, 2, 8, 4, 3, 9” in which the IDs are arranged in descending order of the received illuminance value, and is stored in the illuminance distribution storage unit 15. Illuminance distribution information “(2,1), (1,1), (3,1), (2,2), (1,2), (3,2), (2,3), (1, 3) and (3, 3) ”are sequentially associated with each other, and the positions where the displays 2a to 2e and 2g to 2i other than the ID“ 6 ”are arranged are detected.

  As a result, the relative position detection unit 13 has the ID “1” arranged at the position (1, 1), the ID “7” arranged at the position (3, 1), and the ID “5” (2, 2). ID “2” is arranged at (1,2), ID “8” is arranged at (3,2), ID “4” is arranged at (2,3), and ID “3”. Is located at (1,3) and ID “9” is located at (3,3). Further, the relative position detection unit 13 stores the detected positions of the displays 2a to 2i in the position information storage unit 14 in association with the IDs assigned to the displays 2a to 2i.

By operating as described above, the display control device 1 detects the display 2f arranged at a predetermined basic position (position (2, 1)) among the connected displays 2a to 2i, and the basic position Based on the illuminance value of each of the displays 2a to 2i obtained by lighting the display 2f disposed in the position, the positions of the connected displays 2a to 2i are detected. Then, the display control device 1 performs processing according to the detected position of each of the displays 2a to 2i, for example, increases the brightness of only a specific column, based on the ID assigned to the displays 2a to 2i. It can be carried out.
Moreover, if the basic position detection part 12 specifies the display 2f which detected the 2nd largest illuminance value 3 times, it will identify the display 2f arrange | positioned in the basic position by stopping the operation | movement which turns on one by one in order. And the time for detecting the arranged values of the displays 2a to 2i can be shortened.

  Further, the display control device 1 can detect the arrangement positions of the displays 2a to 2i without the operation of the user or the administrator after the displays 2a to 2i constituting the multi-display 20 are connected. it can. This eliminates the need for a user, administrator, or the like to make individual settings for the displays 2a to 2i in accordance with the arrangement positions of the displays 2a to 2i, making it easy to set position information and improving convenience. improves. In addition, since the arrangement position can be set without using a remote control for operating the display, it is possible to prevent erroneous operation of the display by the remote control.

  In addition, the display connected to the display control device 1 needs to have an illuminance sensor. However, a display having an illuminance sensor is widely used in order to adjust the luminance according to ambient brightness (external light). So you can use it. That is, it is not necessary to add hardware or the like that configures a special function to the display connected to the display control apparatus 1, and an increase in cost when configuring a multi-display system can be suppressed.

In the present embodiment, the multi-display 20 having a size in which the display in which the illuminance sensor is arranged at the lower portion of the right edge of the bezel is arranged in 3 rows and 3 columns has been described, but the arrangement position of the illuminance sensor and the size of the multi-display are different. A modification will be described.
FIG. 7 is a schematic diagram showing a case of a multi-display having a size of 3 rows and 4 columns, in which the illuminance sensor is arranged at the lower part of the right peripheral edge of the bezel. Each frame indicates a display, a black circle (●) indicates an illuminance sensor, and the number on each frame indicates the number of times the second highest illuminance value is detected when each display is turned on one by one. ing. In this case, the position (2, 1) is the basic position, and the display control apparatus can detect the position where each display is arranged by the above-described processing.

  FIG. 8 is a schematic view showing the case of a multi-display having a size of 4 rows and 4 columns, in which the illuminance sensor is arranged at the lower part of the right peripheral edge of the bezel. In FIG. 8, as in FIG. 7, each frame indicates a display, a black circle (●) indicates an illuminance sensor, and the number marked on each frame is the second when each display is turned on one by one. The number of times that a high illuminance value is detected is shown. In this case, the position (2, 1) is the basic position.

Subsequently, in a multi-display having a size of 4 rows and 4 columns, when the illuminance sensors are arranged at the upper part of the right peripheral edge of the bezel, the lower part of the left peripheral part of the bezel, and the upper part of the left peripheral part of the bezel, respectively, FIG. It shows in FIG.10 and FIG.11.
As shown in FIG. 9, when the illuminance sensor is arranged at the upper part of the right peripheral edge of the bezel, the basic position is the position (3, 1). As shown in FIG. 10, when the illuminance sensor is arranged at the lower part of the left peripheral edge of the bezel, the basic position is the position (4, 2). As shown in FIG. 11, when the illuminance sensor is arranged on the upper left edge of the bezel, the basic position is the position (4, 3).

In the case where the illuminance sensor is arranged at the center of the long side (upper or lower) of the periphery of the display and the short side (right or left) of the periphery of the display, as shown below, “2 The basic position where the “display that detects the third largest illuminance value three times” cannot be uniquely determined.
FIG. 12 is a diagram showing the distribution of the number of times each display outputs the second largest illuminance value when the illuminance sensor is arranged on the right side of the upper peripheral edge of the bezel in a multi-display having a size of 4 rows and 4 columns. is there. As shown in the figure, since there is no display that outputs the second largest illuminance value, the basic position cannot be determined in advance.
The long side of the bezel also includes four corner regions that overlap the short side of the bezel.

FIG. 13 shows the distribution of the number of times each display outputs the second highest illuminance value when the illuminance sensor is arranged at the center of the right peripheral edge of the bezel in a multi-display having a size of 4 rows and 4 columns. FIG. As shown in the figure, the display that outputs the second largest illuminance value has two positions (2, 1) and (3, 1), and the position is obtained only by “secondly detecting the illuminance value three times”. Cannot be uniquely identified.
In other words, the display connected to the multi-display device of the present invention is a portion on the short side of the bezel that is in contact with the short side of the display portion of the display, and the illuminance sensor is arranged in one of the ranges excluding the central portion. Need to be.

Next, a case where the size is m rows and n columns (m × n; m> n ≧ 2, and m and n are natural numbers) and the illuminance sensors are arranged in four places will be described below. When the position of the display is indicated, the position (1, 1) is set with the upper left position as the base point.
1. 1. When placed at the bottom of the right edge of the short side of the bezel 2. When placed on the upper right edge of the short side of the bezel 3. When placed in the lower part of the left edge of the short side of the bezel When placed on the upper left edge of the short side of the bezel

[1. When the illuminance sensor is at the bottom of the right edge of the short side of the bezel]
FIG. 14 is a schematic diagram showing a case of a multi-display having a size of m rows and n columns (m × n) in which the illuminance sensor is arranged at the lower portion of the right edge of the short side of the bezel. In FIG. 14, as in FIG. 7, each frame indicates a display, a black circle (●) indicates an illuminance sensor, and the number marked on each frame is the second when each display is turned on one by one. The number of times that a high illuminance value is detected is shown. In this case, the position (2, 1) is the basic position.
When the illuminance sensor is at the lower part of the right edge of the short side of the bezel, when the display arranged at the position (i, j) (1 ≦ i ≦ m, 2 ≦ j ≦ n) is turned on, the position (i, j− The display arranged in 1) outputs the second largest illuminance value.
When the display arranged at the position (i, 1) (2 ≦ i ≦ m) is turned on, the display arranged at the position (i−1, 1) outputs the second largest illuminance value. When the display arranged at the position (1, 1) is turned on, the display arranged at the position (2, 1) outputs the second largest illuminance value.

The number of times each display detects the second largest illuminance value is as follows.
0 times: Display arranged at position (i, n), (1 ≦ i ≦ m)
1 time: display arranged at position (i, j), (1 ≦ i ≦ m, 2 ≦ j ≦ n−1) and position (m, 1) 2 times: position (i, 1), (i = 1 or 3 ≦ i ≦ m−1) Display 3 times: Display disposed at position (2, 1) That is, when the illuminance sensor is disposed at the lower part of the right edge of the short side of the bezel, The position (2, 1) is the basic position.

[2. When the illuminance sensor is at the top of the right edge of the short side of the bezel]
When the illuminance sensor is at the upper part of the right edge of the short side of the bezel, when the display arranged at the position (i, j) (2 ≦ i ≦ m, 1 ≦ j ≦ n) is turned on, the position (i−1, The display arranged in j) outputs the second largest illuminance value.
When the display arranged at the position (i, 1) (1 ≦ i ≦ m−1) is turned on, the display arranged at the position (i + 1, 1) outputs the second largest illuminance value. When the display arranged at the position (m, 1) is turned on, the display arranged at the position (m-1, 1) outputs the second largest illuminance value.

The number of times each display detects the second largest illuminance value is as follows.
0 times: Display arranged at position (i, n) (1 ≦ i ≦ m)
1 time: position (i, j) (1 ≦ i ≦ m, 2 ≦ j ≦ n−1) and display arranged at position (1, 1) 2 times: position (i, 1) (2 ≦ i ≦ m−2 or i = m) Display 3 times: Display located at position (m−1,1) In other words, if the illuminance sensor is placed at the upper right edge of the short side of the bezel, the position (M-1, 1) is the basic position.

[3. When the illuminance sensor is at the bottom of the left edge of the short side of the bezel]
When the illuminance sensor is at the upper part of the right edge of the short side of the bezel, when the display arranged at the position (i, j) (1 ≦ i ≦ m, 1 ≦ j ≦ n−1) is turned on, the position (i, j The display arranged at j + 1) outputs the second largest illuminance value.
When the display arranged at the position (i, n) (2 ≦ i ≦ m) is turned on, the display arranged at the position (i−1, n) outputs the second largest illuminance value. When the display arranged at (1, n) is turned on, the display arranged at the position (2, n) outputs the second largest illuminance value.

The number of times each display detects the second largest initial value is as follows.
0 times: display arranged at position (i, 1), (1 ≦ i ≦ m) 1 time: position (i, j), (1 ≦ i ≦ m, 2 ≦ j ≦ n−1), and position Display placed at (m, n) 2 times: Display placed at position (i, n), (i = 1 or 3 ≦ i ≦ m−1) 3 times: Placed at position (2, n) Display.
That is, when the illuminance sensor is arranged at the lower part of the left side periphery of the short side of the bezel, the position (2, n) is the basic position.

[4. When the illuminance sensor is on the upper left edge of the short side of the bezel]
When the illuminance sensor is at the upper part of the left side periphery of the short side of the bezel, when the display arranged at the position (i, j) (1 ≦ i ≦ m, 1 ≦ j ≦ n−1) is turned on, the position (i, j + 1) ) Outputs the second largest illuminance value.
When the display arranged at the position (i, n) (1 ≦ i ≦ m−1) is turned on, the display arranged at the position (i + 1, n) outputs the second largest illuminance value. Further, when the display arranged at the position (m, n) is turned on, the display arranged at the position (m-1, n) outputs the second largest illuminance value.

The number of times each display detects the second largest illuminance value is as follows.
0 times: Display arranged at position (i, 1) (1 ≦ i ≦ m)
1 time: position (i, j) (1 ≦ i ≦ m, 2 ≦ j ≦ n−1) and display arranged at position (1, n) 2 times: position (i, n) (2 ≦ i ≦ m−2 or i = m) Display 3 times: Display located at position (m−1, n) That is, if the illuminance sensor is placed at the upper right edge of the short side of the bezel, the position (M-1, 1) is the basic position.

  As described above, regardless of the size of the multi display, the basic position (the second highest illuminance value is detected according to the size (row and column) of the multi display and the position where the illuminance sensor of the display is arranged. The position where the display is placed is uniquely determined. Thereby, the display control apparatus 1 of this invention can detect the position where each display which comprises a multi display is arrange | positioned irrespective of the size of a multi display. The minimum size of the multi-display that can detect the arrangement position of the display to which the display control device of the present invention is connected is 2 × 3 (2 × 3). That is, if m ≧ 2 and n ≧ 3, the display control apparatus 1 according to the present invention is arranged such that the basic position detector 12 is arranged at the basic position in a multi-display composed of displays arranged in a matrix. Displayed display can be detected. And the relative position detection part 13 detects the position where the other display is arrange | positioned by lighting the display detected by the basic position detection part 12. FIG. Thereby, the display control apparatus 1 has high versatility capable of detecting the display arrangement position regardless of the size and the arrangement position of the illuminance sensor.

The relative position detection unit 13 assigns IDs assigned to the displays 2a to 2i in the order of connection so that the displays 2a to 2i can be easily controlled according to the positions where the displays 2a to 2i are arranged. It may be corrected. For example, “1”, “2”, and “3” are assigned to the displays 2 a to 2 c with the display arranged at the position (1, 1) as a base point, and “6”, “5”, “ 4 ”and“ 7 ”,“ 8 ”, and“ 9 ”are reassigned to the displays 2g to 2i.
Thus, even when the display is connected to the display control device 1 in a random order independent of the arrangement position, the display control apparatus 1 regularly reassigns the ID according to the arrangement position of each display. The user can easily recognize the display arrangement position by the ID.

  In the present embodiment, the illuminance distribution storage unit 15 has a multi-display size of 3 rows and 3 columns (3 × 3), and the illuminance sensors 21a to 21i are arranged at the lower part of the right edge of the short side of the bezel. However, the present invention is not limited to this, but the present invention is not limited to this, but the present invention is not limited to this. You may make it memorize | store beforehand the illumination distribution information of each combination of the upper part of a left side periphery, the lower part of a short side right side periphery, and the upper part of a short side right side periphery. And based on the information input by the operation of the user and manager of a multi display, any one combination is selected and the arrangement position of the connected display is detected. Thereby, the arrangement position of the connected display can be detected regardless of the arrangement position of the illuminance sensor and the size of the multi-display.

  Further, the illuminance distribution storage unit 15 may store illuminance distribution information in which positions are arranged in descending order of illuminance values detected by the respective illuminance sensors when a display arranged at a position other than the basic position is turned on. Good. As a result, the relative position detection unit 13 turns on the display arranged at the basic position to detect the position of the other display, and then turns on the display arranged at other than the basic position to verify the position of each display. can do. Thereby, when the detection error etc. of the illuminance value of the illuminance sensor occur, it is possible to prevent erroneous detection of the arrangement position of the display.

  The present invention can be used for digital signage using a large screen combining a plurality of displays.

1 Display controller 2, 2a, 2b, 2c, 2d, 2e, 2f, 2g, 2h, 2i Display 3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h, 3i Serial cable 21a, 21b, 21c, 21d , 21e, 21f, 21g, 21h, 21i Illuminance sensor 11 Control unit 12 Basic position detection unit 13 Relative position detection unit 14 Position information storage unit 15 Illuminance distribution storage unit 20 Multi display 100 Multi display system

Claims (6)

A rectangular display unit; an outer frame that surrounds the outer periphery of the display unit; and an illuminance sensor that is disposed at any one of the outer frames in contact with the short side of the display unit and excluding the center of the short side The display units are sequentially turned on one by one with respect to a plurality of display devices arranged in a matrix, and the plurality of display devices are selected in accordance with the illuminance values detected by the illuminance sensors. A basic position detector that identifies a display device arranged at a predetermined basic position,
The display device specified by the basic position detection unit is turned on, and the plurality of display devices are arranged at any position of the matrix based on the illuminance value output from the illuminance sensor of the plurality of display devices. And a relative position detection unit for detecting whether or not. The basic position detection unit calculates the second highest illuminance value among the illuminance values output from the illuminance sensors included in the plurality of display devices each time one of the plurality of display devices is sequentially turned on. The illuminance sensor to be output is detected, and the display device having the illuminance sensor that outputs the second largest illuminance value three times is specified as the display device arranged at the basic position. The display control apparatus according to 1. When the basic position detecting unit identifies the display device having the illuminance sensor that outputs the second largest illuminance value three times, the basic position detecting unit stops turning on the plurality of display devices one by one in order, and the relative position detecting unit The display control device according to claim 2, wherein a position where the plurality of display devices are arranged is detected. The position in the matrix specified by the basic position detection unit is determined by the size of the matrix in which the plurality of display devices are arranged and the position in which the illuminance sensors of the plurality of display devices are arranged. The display control apparatus according to any one of claims 1 to 3. Illuminance distribution information in which the order of the illuminance values output from the illuminance sensor when the display device identified by the basic position detection unit is turned on and the respective positions in the matrix are associated with each other. It has an illuminance distribution storage unit that stores in advance,
The relative position detection unit compares the illuminance value output from the illuminance sensor of the plurality of display devices with the illuminance distribution information stored in the illuminance distribution storage unit, thereby the plurality of display devices. The display control apparatus according to any one of claims 1 to 4, wherein a position where the is arranged is specified. A rectangular display unit; an outer frame that surrounds the outer periphery of the display unit; and an illuminance sensor that is disposed at any one of the outer frames in contact with the short side of the display unit and excluding the center of the short side The display units are sequentially turned on one by one with respect to a plurality of display devices arranged in a matrix, and the plurality of display devices are selected in accordance with the illuminance values detected by the illuminance sensors. Identifying a display device arranged at a predetermined basic position of
The display device identified by the basic position detection unit is turned on, and the plurality of display devices are arranged at any position of the matrix based on the illuminance value output from the illuminance sensor of the plurality of display devices. And a process for detecting whether or not the display control method is provided.

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