JP5761359B2 - Image display system, control device, and display module - Google Patents

Description

  The present invention relates to an image display system, a control device, and a display module that display an image on an image display device configured by arranging a plurality of display modules.

  There is known an image display device in which a plurality of display modules in which a plurality of light emitting elements are arranged at equal intervals are arranged in the vertical and horizontal directions to constitute one large screen as a whole. When joining display modules constituting such an image display device, if the gap between the adjacent display modules becomes wider than the distance between adjacent light emitting elements in the display module due to installation displacement, The seam portion appears as a dark line, causing image quality degradation.

  However, it takes installation time and installation cost to arrange all the display modules so that the distance between the seams is the same as the distance between the light emitting elements. Therefore, conventionally, among the plurality of light emitting elements arranged in the display module, the brightness of the light emitting element in the vicinity of the joint is corrected so as to be higher than the brightness of the light emitting element in the center portion, thereby making the dark line in the joint portion inconspicuous. (For example, refer to Patent Document 1).

JP 2004-86165 A (paragraph 0289)

  However, in the above-mentioned Patent Document 1, it is not considered how much the luminance of the light emitting elements in the vicinity of the joint of each display module is corrected, that is, how to set the luminance correction value. For example, when the luminance correction is performed with the same correction value for each display module, since the interval varies depending on the set of display modules, there is a problem in that a seam portion where dark lines are not eliminated remains and deterioration in image quality cannot be prevented. . In addition, when the interval between the seams between the display modules is narrower than the interval between the light emitting elements, luminance correction with a luminance correction value that makes the luminance of the light emitting elements in the vicinity of the seam higher than the luminance of the light emitting elements in the central portion, There is a problem that the joint portion becomes a bright line and causes deterioration in image quality.

  SUMMARY An advantage of some aspects of the invention is that it provides an image display system capable of preventing the deterioration of image quality by making a joint portion between display modules inconspicuous.

An image display system according to the present invention corresponds to a control device that corrects luminance of image data composed of a plurality of input pixels and outputs corrected image data, and the plurality of pixels of the image data. A plurality of light emitting elements and a plurality of display modules to which the corrected image data from the control device is input, and the image display device configured by arranging the plurality of display modules has the corrected An image display system for displaying an image corresponding to image data, wherein the control device includes: a first display module among the plurality of display modules; and a second display module adjacent to the first display module; When an interval value between the pixels is input, a brightness correction value for correcting the brightness of the plurality of pixels of the image data corresponding to the input interval value is output. A brightness correction value output unit and the brightness correction value output from the brightness correction value output unit are added to the brightness of the plurality of pixels, respectively, so that the second display is provided in the first display module. A luminance correction unit that corrects luminances of the plurality of pixels on the first line adjacent to the module and on the second line in the second display module and adjacent to the first line; And the luminance correction value output unit alternately sets luminance correction values for correcting the plurality of pixels on the first line to different values, and the luminance of the plurality of pixels on the first line. And the luminance correction value for correcting the luminance of the pixels on the second line adjacent to the plurality of pixels on the first line are a predetermined difference excluding 0. The brightness correction value as Force, and the luminance correction value for correcting the luminance of the plurality of pixels in the first on-line, a value lower than the luminance correction value for correcting the luminance of the pixels on the second line adjacent, It is a value that alternates with a value higher than the luminance correction value for correcting the luminance of the pixels on the adjacent second line .

The control device according to the present invention corrects the luminance of image data composed of a plurality of input pixels, and the corrected image data is arranged with a plurality of light emitting elements corresponding to the plurality of pixels of the image data. A control device that outputs to the plurality of display modules and displays an image corresponding to the corrected image data on an image display device configured by arranging the plurality of display modules. When the interval value between the first display module and the second display module adjacent to the first display module is input, the plurality of the image data corresponding to the input interval value. A luminance correction value output unit for outputting a luminance correction value for correcting the luminance of the pixel of the pixel, and the luminance correction value output from the luminance correction value output unit as the luminance of the plurality of pixels, respectively By calculating, on the first line in the first display module and adjacent to the second display module, and in the second display module and adjacent to the first line. A luminance correction unit that corrects the luminance of the plurality of pixels on the second line, and the luminance correction value output unit outputs a luminance correction value for correcting the plurality of pixels on the first line. A brightness correction value for correcting the brightness of the plurality of pixels on the first line, and a value on the second line adjacent to the plurality of pixels on the first line, which are alternately different values. The brightness correction value for correcting the brightness of the plurality of pixels on the first line by outputting the brightness correction value so that the brightness correction value for correcting the brightness of the pixel has a predetermined difference excluding 0 On the adjacent second line A value lower than the luminance correction value for correcting the luminance of the pixel, a value higher than the luminance correction value for correcting the luminance of the pixels on the second line adjacent a value such that alternating It is characterized by.

The display module according to the present invention constitutes an image display device in which a plurality of arrays are displayed and displays an image, and is a display module in which a plurality of light emitting elements are arrayed, and corresponds to a spacing value between adjacent display modules. A luminance correction value storage unit that stores a luminance correction value for correcting the luminance of a plurality of pixels constituting the input image data, and the luminance correction value stored in the luminance correction value storage unit. A luminance correction unit that corrects the luminance of the plurality of pixels corresponding to the plurality of light emitting elements on the line adjacent to the adjacent display module among the plurality of pixels by adding to the luminance of each of the plurality of pixels. with the door, the luminance correction value storage unit, and alternately to different values the luminance correction value for correcting said plurality of pixels located on the lines, the plurality of pixels on the line Storing the luminance correction value, the luminance correction value so as to have a predetermined difference, except the luminance correction value with the 0 of the pixel on the line to the adjacent adjacent to each of the plurality of pixels on the line, the first The luminance correction value for correcting the luminance of the plurality of pixels on one line is lower than the luminance correction value for correcting the luminance of the pixel on the adjacent second line, and the adjacent second It is a value that alternates with a value higher than the luminance correction value for correcting the luminance of the pixels on this line .

  According to the image display system, the control device, and the display module of the present invention, the luminance of the light emitting element in the vicinity of the seam is corrected with the brightness correction value according to the interval between the seams between the display modules. The resulting dark line or bright line can be made inconspicuous and image quality deterioration can be prevented.

1 is a configuration diagram of an image display system according to Embodiment 1. FIG. FIG. 4 illustrates a display module according to Embodiment 1; FIG. 3 is a diagram for explaining a gap between joints between display modules according to Embodiment 1; FIG. 3 is a diagram for explaining a correspondence relationship between the image display device and image data in the first embodiment. FIG. 3 illustrates an example of an image display device according to Embodiment 1; 3 is a flowchart showing an operation according to the first embodiment. FIG. 6 is a diagram illustrating an example of a luminance correction value stored in a correspondence information storage unit according to the first embodiment. FIG. 6 is a diagram for explaining an example of a method for setting a luminance correction value according to the first embodiment. FIG. 6 is a diagram for explaining luminance correction of image data according to the first embodiment. 6 is a diagram for explaining another example of luminance correction of image data according to Embodiment 1. FIG. FIG. 10 is a diagram illustrating another example of the brightness correction value stored in the correspondence information storage unit according to the first embodiment. 6 is a diagram for explaining another example of luminance correction of image data according to Embodiment 1. FIG. 6 is a diagram for explaining another example of luminance correction of image data according to Embodiment 1. FIG. FIG. 3 is a configuration diagram of an image display system according to a second embodiment. 9 is a flowchart showing an operation according to the second embodiment. FIG. 6 is a configuration diagram of an image display system according to a third embodiment. FIG. 6 is a configuration diagram of a captured image analysis unit according to a third embodiment. 10 is a flowchart showing a joint interval calculation process operation according to the third embodiment. The figure which represented the image display apparatus corresponding to the captured image data which concerns on Embodiment 3 with a rectangular coordinate system.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram of an image display system according to the first embodiment. FIG. 2 is a diagram for explaining the display module according to the first embodiment. FIG. 3 is a diagram for explaining the interval between the seams between the display modules according to the first embodiment. FIG. 4 is a diagram for explaining the correspondence between the image display device and the image data in the first embodiment. FIG. 5 is a diagram illustrating an example of the image display apparatus according to the first embodiment. FIG. 6 is a flowchart showing the operation according to the first embodiment. FIG. 7 is a diagram illustrating an example of the luminance correction value stored in the correspondence information storage unit according to the first embodiment. FIG. 8 is a diagram for explaining an example of the method of setting the luminance correction value according to the first embodiment. FIG. 9 is a diagram for explaining luminance correction of image data according to the first embodiment. FIG. 10 is a diagram for explaining another example of luminance correction of image data according to the first embodiment. FIG. 11 shows another example of the luminance correction value stored in the correspondence information storage unit according to the first embodiment. FIG. 12 is a diagram for explaining another example of luminance correction of image data according to the first embodiment. FIG. 13 is a diagram for explaining another example of luminance correction of image data according to the first embodiment.

  As shown in FIG. 1, the image display system according to the first embodiment of the present invention corrects the luminance of input image data for display and outputs the corrected image data. And a plurality of display modules 2 for outputting image data. The image data is data regarding luminance information of a plurality of pixels constituting the image, and is input to the control device 1 from an external device such as a PC (Personal Computer) or a TV (Television).

  First, details of the display module 2 will be described. As shown in FIG. 2, the display module 2 has a plurality of light emitting elements 4 arranged at equal intervals in the vertical and horizontal directions. Here, the light emitting elements 4 are arranged in 10 rows × 10 columns in one display module 2. The light emitting element 4 is composed of an LED (Light Emitting Diode), and one light emitting element 4 corresponds to one pixel on the image data. That is, one pixel is expressed by one light emitting element 4. By arranging a plurality of display modules 2 in which a plurality of light emitting elements 4 are arranged in the vertical and horizontal directions, an image display device 3 that displays one large screen image as a whole is configured.

  At this time, the display modules 2 are arranged such that the interval between the adjacent display modules 2, that is, the interval between the joints, is the same as the interval between the light emitting elements 4 arranged in the display module 2. As shown in FIG. 3, the gap between the display module 2-1 and the display module 2-2 is such that the light emitting elements 4 arranged in the rightmost column of the display module 2-1 and the display module 2-2. It is the distance between the light emitting elements 4 arranged in the leftmost column. The same applies to the vertical seam spacing, and the seam spacing between the display module 2-1 and the display module 2-3 includes the light emitting elements 4 arranged in the bottom row of the display module 2-1, This is the distance between the light emitting elements 4 arranged in the uppermost row of the display module 2-4. When the interval between the seams between the display modules 2 and the interval between the adjacent light emitting elements 4 in the display module 2 are not the same, the display module 2 is misplaced.

  Returning to FIG. 1, the details of the image display system will be described. The control device 1 includes a correspondence information storage unit 11, a luminance correction value output unit 12, a luminance correction unit 13, and an image dividing unit 14. The display module 2 includes a light emission control unit 21.

  In the correspondence information storage unit 11, a joint interval value between adjacent display modules 2 and a luminance correction value are stored in association with each other. The luminance correction value is a value for correcting the luminance of the pixels constituting the image data, and the value differs depending on the interval value of the joint between the display modules 2. In other words, when the interval value of the joint between the display modules 2 is larger than the interval value between the adjacent light emitting elements 4 in the display module 2, the luminance correction value is set to (correction) the luminance of the correction target pixel than when the image data is input. When the interval value of the joint between the display modules 2 is smaller than the interval value between the light emitting elements 4, the luminance of the correction target pixel is made lower than that at the time of image data input. Value. Details of the luminance correction value will be described later.

  The brightness correction value output unit 12 receives the interval value of the joint between the first display module and the second display module adjacent to the first display module, and the display module number corresponding to the interval value. Is done. When these pieces of information are input, the luminance correction value output unit 12 acquires a luminance correction value corresponding to the input interval value from the correspondence information storage unit 11. Then, the luminance correction value output unit 12 outputs the acquired luminance correction value and display module number to the luminance correction unit 13. For example, when the interval value between the display module M1 and the display module M2 shown in FIG. 4 is input, the luminance correction value output unit 12 displays the numbers of the display modules M1 and M2 and the luminance correction value corresponding to the interval value. Will be output.

  Based on the brightness correction value input from the brightness correction value output unit 12 and the display module number, the brightness correction unit 13 includes the first display module and the second display module among the plurality of pixels constituting the input image data. The luminance of the pixel corresponding to the light emitting element 4 in the vicinity of the joint with the display module is corrected, and the image data after the luminance correction is output. Specifically, the luminance correction unit 13 specifies pixels corresponding to the light emitting elements 4 in the vicinity of the joint between the first display module and the second display module as correction target pixels from the display module numbers, and these pixels. The brightness correction value is added to.

  Here, the vicinity of the seam refers to the first line in the first display module and adjacent to the second display module. In FIG. 4, when the first display module corresponds to the display module M1 and the second display module corresponds to the display module M2, the rightmost column of the display module M1 is the first line. That is, the brightness correction unit 13 corrects the brightness of the pixel group A including a plurality of pixels (pixels in the rightmost column) corresponding to the plurality of light emitting elements 4 on the first line.

  In addition to the first line, the vicinity of the seam may include a second line in the second display module and adjacent to the first display module. In FIG. 4, the leftmost column of the display module M2 is the second line. The brightness correction unit 13 also corrects the brightness of the pixel group B composed of a plurality of pixels (pixels in the leftmost column) corresponding to the plurality of light emitting elements 4 on the second line. By doing so, the luminance correction unit 13 corrects the luminance of the pixel group A and the pixel group B to be displayed on the light emitting elements 4 on both sides of the joint portion between the display modules 2. Or even if a bright line occurs, this dark line or bright line can be eliminated in a balanced manner.

  The plurality of light emitting elements 4 on the first (second) line does not necessarily indicate all the light emitting elements 4 in the row or column in the display module 2. That is, the luminance correction unit 13 does not necessarily perform luminance correction on all the pixels constituting the pixel group A (pixel group B). Further, the first line and the second line are not limited to one row or one column in the display module, and may be a plurality of rows or a plurality of columns.

  The image dividing unit 14 divides the image data after luminance correction input from the luminance correcting unit 13 into a plurality of image data (hereinafter referred to as divided image data), and each of the plurality of divided image data corresponds to each display module. Output to 2. The image dividing unit 14 grasps the correspondence between the divided image data and the display module 2.

  The image dividing unit 14 may not divide the image data, and the luminance correcting unit 13 may output the image data after the luminance correction to each display module 2 as it is. In that case, each display module 2 receives only the data for the display itself of the transmitted image data.

  The light emission control unit 21 reads the luminance of the divided image data output from the image dividing unit 14 and causes the light emitting element 4 to emit light based on the read luminance. Since a predetermined pixel (for example, the pixel group A in FIG. 4) of the plurality of pixels constituting the divided image data has been subjected to luminance correction by the luminance correction unit 13, as a result, a light emitting element corresponding to the luminance corrected pixel 4 (for example, the light emitting element 4 on the first line in FIG. 4) is corrected. That is, the luminance correction unit 13 corrects the luminance of the pixels constituting the divided image data, and as a result, the luminance of the light emitting element 4 is corrected. When the light emitting element 4 emits light, a divided image is displayed on the display module 2, and one image (an image corresponding to the corrected image data) is displayed on the image display device 3. .

  Next, the operation of the first embodiment of the present invention will be described with reference to FIGS. Here, the image display device 3 shown in FIG. 5 will be described as an example. The image display device 3 shown in FIG. 5 is configured by arranging the display modules 2 in which the light emitting elements 4 are arranged in 10 rows × 10 columns in 2 rows × 3 columns. The interval value between the light emitting elements 4 is 4 mm. The interval value between the display modules 2-5 and 2-6 constituting the image display device 3 is 8 mm, and the interval is wider than 4 mm. The interval value between the display modules 2-7 and 2-10 is 2 mm. The interval is narrower than 4 mm, and in both cases, installation displacement occurs. Therefore, when an image that is not subjected to luminance correction is displayed on the image display device 3, a dark line is generated at the joint between the display modules 2-5 and 2-6, and the joint between the display modules 2-7 and 2-10. As a result, a bright line is generated in the image display device 3, which causes deterioration of image quality.

  First, as shown in FIG. 6, the brightness correction setting processing operation in the control device 1 before image data is input will be described (step S1 to step S4).

  When the display module 2 is arranged and the image display device 3 is assembled, the interval value of the joint between the adjacent display modules 2 and the display module number are input to the luminance correction value output unit 12 from the outside of the control device 1. (Step S1).

  The interval value of the joint between the adjacent display modules 2 is measured by a person in charge of installation of the display module 2, for example. This person in charge of installation installs each of the vertical and horizontal groups as shown in display modules 2-5, 2-6, display modules 2-6, 2-7, display modules 2-5, 2-8,. The interval value of the seam is measured for the display module 2. Here, since there is a misalignment between the display modules 2-5 and 2-6 and between the display modules 2-7 and 2-10, the display module number and the interval value (8 mm, 2 mm) of the joint are luminance. It is input to the correction value output unit 12.

  When the interval value of the seam of each set in which installation deviation has occurred is input, the luminance correction value output unit 12 acquires the luminance correction value corresponding to each interval value (8 mm, 2 mm) from the corresponding information storage unit 11. (Step S2).

  As shown in the table (a) of FIG. 7, the correspondence information storage unit 11 stores a luminance correction value corresponding to the joint interval value. The brightness correction value is a value that increases the brightness when the image data is input when the interval value is larger than 4 mm, and the brightness is lower than that when the image data is input when the interval value is less than 4 mm. A specific value may be a value that is proportional to the interval value, or may be determined based on an empirical rule. Here, as an example, the luminance correction value corresponding to the interval value 8 mm is 8, and the luminance correction value corresponding to the interval value 2 mm is −3, and the luminance correction unit 13 acquires these values. In the table (a), the brightness correction value corresponding to the interval value from 1 mm to 8 mm in 1 mm units is stored. However, the present invention is not limited to this, and the step size of the interval value and the range of the interval value are arbitrary. It can be set to. The same applies to the following.

  Further, as shown in the table (b) of FIG. 7, the correspondence information storage unit 11 may store a plurality of luminance correction values corresponding to the joint interval values. In this case, the brightness correction value is stored as an array, for example. Even when the luminance correction values are arranged in this manner, the values may be proportional to the interval values or may be determined based on empirical rules as long as the values correspond to the interval values. Here, as an example, the luminance correction value corresponding to the interval value of 8 mm is stored in the correspondence information storage unit 11 as k8, and the luminance correction value corresponding to the interval value of 2 mm is stored as k2. An example of this setting method is shown below.

  First, a plurality of base values that are arbitrary values that do not depend on the interval value of the joint between the display modules 2 are determined. For example, when the light emitting elements 4 are arranged in 10 rows × 10 columns in the display module 2, the number of base values may be set to 10 (number 1 to number 10). In the example of FIG. 8, the base values are set to +3, +1, +3, +2,. When the number of light emitting elements 4 differs vertically and horizontally (for example, 10 rows × 15 columns), two types of 10 base values and 15 base values may be prepared.

  The plurality of base values set in this way are each multiplied by a coefficient corresponding to the joint interval value. For example, when the joint interval value increases by 50% from 4 mm, 1.5 is multiplied, and when the joint interval value decreases by 50, -1.5 is multiplied. In this way, the brightness correction value is obtained by multiplying the base value by the coefficient corresponding to the interval value of the joint.

  In the example of FIG. 8, when the interval value of the joint is 8 mm, the interval value increases from 4 mm to 100%, so that a plurality of base values are multiplied by a coefficient 2 respectively. Therefore, the luminance correction value k8 is composed of +6, +2, +6, +4,. When the interval value of the seam is 2 mm, the interval value is reduced by 50% from 4 mm, so that a plurality of base values are respectively multiplied by a coefficient −1.5. Therefore, the luminance correction value k2 is configured from −4.5, −1.5, −4.5, −3,.

  As described above, the correspondence information storage unit 11 has the luminance correction values as shown in the tables (a) and (b) of FIG. 7, that is, the luminance correction values corresponding to the joint interval values between the display modules 2. Since it is stored, even if the interval value of the seam varies depending on the set of the display modules 2, it is possible to perform luminance correction suitable for each display module 2. That is, when a dark line is generated at a joint portion in one set of display modules 2, the brightness is corrected by the brightness correction value F that increases the brightness of the display modules 2, while the interval of the seams is set in another set of display modules 2. If the dark line generated at the seam portion is deeper, the display module 2 can be corrected for luminance with a luminance correction value larger than the luminance correction value F described above. Further, when the interval between the seams is narrow in another set of the display modules 2 and a bright line is generated at the seam portion, the brightness correction can be performed with a brightness correction value that lowers the brightness of the display modules 2.

  Returning to FIG. 4, the luminance correction value output unit 12 outputs the luminance correction value acquired from the correspondence information storage unit 11 and the display module number corresponding to the input interval value to the luminance correction unit 13 (step S3). ).

  When the luminance correction value and the display module number are input from the luminance correction value output unit 12, the luminance correction unit 13 holds these and waits (step S4). This completes the brightness correction setting process.

  Next, the processing operation from when image data is input to the control device 1 until the image is displayed on the image display device 3 after the luminance correction setting processing is completed will be described (steps S5 to S8).

  When image data is input from an external device after the luminance correction setting process is completed (step S5), the luminance correction unit 13 displays a display module among a plurality of pixels constituting the image data based on the luminance correction value. The luminance of the pixel at the position corresponding to the vicinity of the joint between the two is corrected (step S6).

  When the luminance correction value shown in the table (a) in FIG. 7 is input from the luminance correction value output unit 12, the luminance correction unit 13, as shown in FIG. An interval value of 8 mm is set for a plurality of pixels (pixel group A1) corresponding to the plurality of light emitting elements 4 in the display module 2-5 and on the line (rightmost column) adjacent to the display module 2-6. The corresponding brightness correction value 8 is added. More specifically, the pixel group A1 indicates the 10th row and 10th column from the 1st row and the 10th column on the image data.

  As described above, when the input interval value is larger than the interval value between the light emitting elements 4 in the display module 2, the luminance correction value output unit 12 is in the display module 2-5 and the display module 2-6. 8 as a luminance correction value corresponding to the interval value of 8 mm so that the luminance of the plurality of pixels (pixel group A1) corresponding to the plurality of light emitting elements 4 on the line adjacent to is higher than the luminance at the time of input. The luminance correction unit 13 outputs the luminance correction value 8 to a plurality of pixels constituting the pixel group A1, and is suitable for dark lines generated at a joint portion between the display module 2-5 and the display module 2-6. Brightness correction can be performed and can be made inconspicuous.

  Further, as described above, the luminance correction unit 13 includes a plurality of pixels (corresponding to the plurality of light emitting elements 4 on the line (leftmost column) adjacent to the display module 2-5 in the display module 2-6). The brightness correction value 8 may be added to the pixel group B1). More specifically, the pixel group B1 indicates the first row and eleventh column to the tenth row and eleventh column on the image data.

  As described above, when the input interval value is larger than the interval value between the light emitting elements 4 in the display module 2, the luminance correction value output unit 12 includes the display module 2-6 in the display module 2-5. The luminance correction value 8 may be output so that the luminance of the plurality of pixels (pixel group B1) corresponding to the plurality of light emitting elements 4 on the adjacent line is higher than the luminance at the time of input. The unit 13 adds the brightness correction value 8 to a plurality of pixels constituting the pixel group B1. By doing so, the luminance of the pixel group A1 and the pixel group B1 displayed on the light emitting elements 4 on both sides of the joint portion between the display modules 2-5 and 2-6 is corrected, so that the dark lines generated in the joint portion are balanced. It can be made inconspicuous.

  Similarly, the luminance correction unit 13 is a pixel in the pixel group C1, D1 (corresponding to the 10th row 21st column to the 10th row 30th column and the 11th row 21st column to the 11th row 30th column on the image data). The brightness correction value -3 corresponding to the interval value of 2 mm is added to the brightness.

  As described above, when the input interval value is smaller than the interval value between the light emitting elements 4 in the display module 2, the luminance correction value output unit 12 is in the display module 2-7 and the display module 2-10. The luminance correction value -3 corresponding to the interval value of 2 mm is output so that the luminance of the plurality of pixels (pixel group C1) corresponding to the plurality of light emitting elements 4 on the line adjacent to is lower than the luminance at the time of input. The brightness correction unit 13 adds the brightness correction value -3 to a plurality of pixels constituting the pixel group C1, and thus is suitable for the bright line generated at the joint portion between the display module 2-7 and the display module 2-10. Brightness correction can be performed and can be made inconspicuous. The same applies to the pixel group D1.

  When the luminance correction value shown in the table (b) of FIG. 7 is input from the luminance correction value output unit 12, the luminance correction unit 13 applies the pixel group A1 (or B1, or both) as shown in FIG. The brightness correction value k8 is added to the pixel group C1 (or D1, or both), and the brightness correction value k2 is added. In this case, among the plurality of pixels whose luminance is corrected, different luminance correction values are added to some pixels and other pixels. For example, among a plurality of pixels constituting the pixel group A1, the luminance correction value 6 is added to some pixels, 2 is added to another pixel, and the luminance correction value 4 is added to the other pixels. Is added. In addition, the luminance correction value −4.5 is added to some of the plurality of pixels constituting the pixel group C1, and the luminance correction value −1.5 is added to some of the other pixels. Is added with a luminance correction value of -3.

  As described above, the luminance correction value output unit 12 is configured such that some of the plurality of pixels (pixel groups A1, B1, C1, and D1) corresponding to the plurality of light emitting elements on the line of the display module 2 and others. Even when a luminance correction value different from that of the pixel is output and the luminance correction unit 13 performs the luminance correction based on the luminance correction value, the interval with respect to the dark line or the bright line generated at the joint portion between the display modules 2 is also determined. A suitable luminance correction according to the value can be performed and can be made inconspicuous.

  Then, the luminance correction unit 13 outputs the image data after adding the luminance correction value (after luminance correction) to the image dividing unit 14.

  The image dividing unit 14 divides the input image data into a plurality of divided image data, and outputs them to the corresponding display modules 2 (step S7).

  When the divided image data is input to each display module 2, the light emission control unit 21 reads the luminance of each pixel constituting the divided image data. And the light emission control part 21 makes each light emitting element 4 light-emit with the read brightness | luminance, and displays a divided image on the display module 2 (step S8).

  At this time, the luminance of the pixel groups A1, B1, C1, and D1 in the divided image data input to the display module 2 is corrected, so that the light emitting element 4 and the display module 2 in the rightmost column of the display module 2-5. The light emitting elements 4 in the leftmost column of −6 are corrected so as to increase the luminance, and the light emitting elements 4 in the lowermost row of the display module 2-7 and the light emitting elements 4 in the uppermost row of the display module 2 become lower in luminance. Will be corrected.

  As a result, when viewed as the entire screen of the image display device 3, the dark line generated at the joint portion between the display modules 2-5 and 2-6 indicates that the luminance of the light emitting element 4 near the joint is in accordance with the interval value. Since it is corrected to be higher, it will not stand out. Further, the bright line generated at the joint portion between the display modules 2-7 and 2-10 is not conspicuous because the luminance of the light emitting element 4 in the vicinity of the joint is corrected so as to decrease according to the interval value.

  As described above, according to the first embodiment of the present invention, the luminance of the light emitting element in the vicinity of the joint is corrected with the luminance correction value corresponding to the interval value of the seam for the display module 2 in which the installation deviation occurs. Therefore, even when the interval between the seams varies depending on the set of the display modules 2, suitable luminance correction is performed for each, and the seam portion of the entire image displayed on the image display device 3 is made inconspicuous, thereby degrading the image quality. Can be prevented.

  Further, when the interval value between the display modules 2 is narrower than that between the light emitting elements 4, luminance correction is performed so as to reduce the luminance of the light emitting elements 4 in the vicinity of the seams, so that the bright line at the seam portion is displayed. It is less noticeable and image quality deterioration can be prevented.

  Moreover, the brightness | luminance of the some pixel displayed on the light emitting element 4 in the both sides of the joint part between the display modules 2 can also be correct | amended, and the dark line or bright line which arises in a joint part can be made inconspicuous with sufficient balance.

  In the meantime, the luminance correction value is stored in the correspondence information storage unit 11, and the luminance correction value output unit 12 acquires the luminance correction value from the correspondence information storage unit 11 and outputs it to the luminance correction unit 13. However, it is not limited to this. When the interval value of the joint is input, the luminance correction value output unit 12 may generate a luminance correction value corresponding to the interval value and output the generated luminance correction value to the luminance correction unit 13. The same applies to the following.

  Here, as shown in the table (c) of FIG. 11, the correspondence information storage unit 11 stores a plurality of luminance correction values corresponding to the interval value of the seam and having a luminance difference of a predetermined value or more. May be. Here, a luminance difference of 5 or more is given. The table (c) stores an array of two luminance correction values. For example, when the interval value is 8 mm, the luminance correction value k10 is an array of +8, +1, +8, +1,. , +8, +1, +8,... +8, and the luminance difference is 7. In the case of an interval value of 2 mm, the luminance correction value k9 is an array of -6, -1, -6, -1,... -1, and -1, -6, -1, -6,. The brightness difference is 5. Therefore, the luminance correction values k9 and k10 have a luminance difference of 5 or more.

  Further, in order to have a predetermined luminance difference, as shown in the table (d) of FIG. 11, a luminance correction value with an opposite sign may be used for a part of the plurality of luminance correction values. For example, when the interval value is 8 mm, the luminance correction value k12 is set to an array of +5, −2, +5, −2,... −2, and an array of −2, +5, −2, +5,. The luminance difference is 7. When the interval value is 2 mm, the luminance correction value k11 is set to an array of -4, +1, -4, +1,... +1 and an array of +1, -4, +1, -4,. The luminance difference is 5. Therefore, the brightness correction values k11 and k12 have a brightness difference of 5 or more. However, even when the brightness correction values of both codes are used in this way, as a whole pixel group subjected to brightness correction, when the interval value between the display modules 2 is larger than the interval value between the light emitting elements 4, When the luminance is higher than that at the time of input and the interval value between the display modules 2 is smaller than the interval value of the light emitting element 4, the luminance must be lower than that at the time of input. Therefore, when the interval value between certain display modules 2 is 8 mm, the luminance correction value may be an array of +5, -2, +5, -2, -2, but the luminance of the entire pixel group is lowered. -5, +2, -5, +2, ..- 5.

  Here, the predetermined luminance difference is set to 5 or more. However, as to how much the predetermined luminance difference is to be given, a suitable value may be calculated in advance by a test or the like. Moreover, the value based on an empirical rule may be sufficient.

  When the luminance correction value output unit 12 outputs, for example, the luminance correction value k10, the luminance correction unit 13 adds the luminance correction value 8 to some pixels of the pixel group A1, as shown in FIG. A luminance correction value 1 is added to the pixel. Therefore, the luminance correction value added to some of the pixels in the pixel group A1 is a value that is a predetermined luminance difference 7 higher than the luminance correction value added to the other pixels. Further, the luminance correction value 8 is added to the pixel in the pixel group B1 adjacent to the pixel to which the luminance correction value 1 in the pixel group A1 is added, and the luminance correction value 8 in the pixel group A1 is added. A luminance correction value 1 lower by a predetermined luminance difference 7 is added to the pixels in the pixel group B1 adjacent to the pixel.

  When the luminance correction value output unit 12 outputs the luminance correction value k12, the luminance correction unit 13 adds the luminance correction value +5 to some pixels of the pixel group A1, as shown in FIG. A luminance correction value of −2 is added to the pixels. Therefore, the luminance correction value added to some of the pixels in the pixel group A1 is a value that is a predetermined luminance difference 7 higher than the luminance correction value added to the other pixels. Further, the luminance correction value +5 is added to the pixel in the pixel group B1 adjacent to the pixel to which the luminance correction value -2 in the pixel group A1 is added, and the luminance correction value +5 in the pixel group A1 is added. The luminance correction value −2 having a predetermined luminance difference of 7 is added to the pixels in the pixel group B1 adjacent to the pixel.

  As described above, the luminance correction value output unit 12 outputs a luminance correction value output to some of the plurality of pixels constituting the pixel group A1 by a predetermined difference from the luminance correction value output to other pixels. A luminance correction value to be output to a pixel adjacent to a part of the pixels of the pixel group A1 among the plurality of pixels constituting the pixel group B1 adjacent to the pixel group A1 as well as other values of the pixel group A1. The luminance correction unit 13 performs a luminance correction based on the luminance correction value, which is lower than the luminance correction value output to the pixel adjacent to the pixel, and thereby the luminance of the plurality of light emitting elements 4 in the vicinity of the joint. Therefore, it is possible to prevent the occurrence of a boundary line between the vicinity of the seam and the central portion (portion other than the vicinity of the seam) in the display module, and further prevent deterioration of the image quality. it can.

  That is, when the interval between the display modules 2 is widened, if the brightness of all the light emitting elements 4 in the vicinity of the joint is corrected to be higher than that at the time of input, the dark line in the joint portion becomes inconspicuous. In the display module, the luminance difference between the central portion of the display module and the vicinity of the joint becomes large (the vicinity of the joint becomes too bright), and a boundary line may be generated between these regions. However, as described above, the luminance of the light emitting element 4 in the vicinity of the joint is thinned out and corrected so that the dark line in the joint can be made inconspicuous, and the boundary generated between the central portion and the vicinity of the joint in the display module. It is also possible to prevent the generation of lines, thereby further preventing image quality deterioration. The same applies to the case of preventing the occurrence of bright lines near the joint between display modules.

  Here, in order to give a predetermined luminance difference between the luminance correction value output to some of the pixels constituting the pixel group and the luminance correction value output to other pixels, the tables (c) and (c) in FIG. As shown in d), a value in which brightness correction values having a predetermined brightness difference are alternately arranged is used, but the present invention is not limited to this. For example, +8, +1, +1, +8,. Thus, it may be aperiodic, or may be arranged so as to have a luminance difference in stages, such as +8, +3, +1, +3, +8,.

Embodiment 2. FIG.
The second embodiment of the present invention will be described below with reference to the drawings. FIG. 14 is a configuration diagram of an image display system according to the second embodiment. FIG. 15 is a flowchart showing the operation according to the second embodiment. Portions corresponding to the configuration of the image display system according to the first embodiment are denoted by the same reference numerals as those in FIG.

  In the image display system according to the second embodiment, as shown in FIG. 14, each display module 2 includes a luminance correction value storage unit 22 and a luminance correction unit 23, and the display module 2 performs luminance correction of the image data. This is different from the first embodiment.

  The luminance correction value storage unit 22 displays the luminance correction value corresponding to the interval value of the seam between the first display module and the second display module input from the luminance correction value output unit 11 of the control device 1 and the display. The module number is stored.

  When the divided image data is input from the image dividing unit 14 of the control device 1, the luminance correction unit 23 configures the divided image data based on the luminance correction value obtained from the luminance correction value storage unit 22 and the display module number. Among the plurality of pixels, the luminance of the pixel corresponding to the light emitting element 4 in the vicinity of the joint between the first display module and the second display module is corrected. That is, the luminance correction unit 23 in the first display module includes the first pixel adjacent to the second display module in the first display module among the plurality of pixels constituting the input divided image data. The luminance of a plurality of pixels corresponding to the plurality of light emitting elements 4 on the line is corrected. The luminance correction unit 23 in the second display module is on a second line within the second display module and adjacent to the first display module among the plurality of pixels constituting the input divided image data. The luminance of a plurality of pixels corresponding to the plurality of light emitting elements 4 is corrected.

  As in the first embodiment, the plurality of light emitting elements 4 on the first (second) line does not necessarily indicate all the light emitting elements 4 in the row or column in the display module 2. Further, the first (second) line is not limited to one row or one column in the display module, and may be a plurality of rows or a plurality of columns.

  The operation in the second embodiment of the present invention will be described with reference to FIGS. As an example for explaining this operation, the image display device 3 shown in FIG. 5 is used as in the first embodiment. The interval value of the joint between the display modules 2 and the conditions such as the combination of the display modules 2 in which the installation deviation occurs are the same as in the first embodiment.

  First, the luminance correction setting processing operation in the display module 2 before image data is input will be described (step S01 to step S05).

  When the display module 2 is arranged and the image display device 3 is assembled, the interval value (8 mm) between the display modules 2-5 and 2-6 shown in FIG. 7 and 2-10 are input to the luminance correction value output unit 12 (2 mm) and the display module number corresponding to the joint interval value (step S01).

  The luminance correction value output unit 12 acquires a luminance correction value corresponding to the input seam interval value (8 mm, 2 mm) from the correspondence information storage unit 11 (step S02).

  Then, the luminance correction value output unit 12 outputs the luminance correction value and the display module number corresponding to the interval value 8 mm to the luminance correction value storage unit 22 of the display modules 2-5 and 2-6, and the display module 2- 7 and 2-10, the brightness correction value corresponding to the interval value of 2 mm and the display module number are output to the brightness correction value storage unit 22 (step S03).

  Each of the display modules 2-5, 2-6, 2-7, 2-10 receives the brightness correction value corresponding to the interval value and the display module number from the brightness correction value output unit 12, and the brightness correction value storage unit. When these are stored in 22 (step S04), the luminance correction unit 23 acquires and holds these pieces of information from the luminance correction value storage unit 22, and stands by (step S05). This completes the brightness correction setting process.

  Next, after the brightness correction setting process is completed, a processing operation from when image data is input to the control device 1 until an image is displayed on the image display device 3 will be described (step S06 to step S09).

  When image data is input from an external device after completion of the brightness correction setting process (step S06), the image dividing unit 14 divides the input image data into a plurality of divided image data, and the corresponding display modules are provided. 2 is output to the luminance correction unit 23 (step S07).

  The luminance correction unit 23 of each of the display modules 2-5, 2-6, 2-7, and 2-10 is based on the luminance correction value that has been held, and is in the vicinity of the joint among the plurality of pixels constituting the divided image data. The luminance of the pixel at the position corresponding to is corrected (step S08). For example, the luminance correction unit 23 in the display module 2-5 includes a plurality of pixels constituting the input divided image data in the display module 2-5 based on the input luminance correction value and the display module number. Then, the luminance of the pixel (pixel in the rightmost column) corresponding to the light emitting element 4 on the line adjacent to the display module 2-6 is corrected. The same applies to the other display modules 2. The luminance of the pixels in the leftmost column in the display module 2-6, the lowermost row in the display module 2-7, and the uppermost row in the display module 2-10 is corrected.

  The light emission control unit 23 of each display module 2-5, 2-6, 2-7, 2-10 reads the luminance of each pixel constituting the luminance-corrected divided image data. And each light emitting element 4 is light-emitted with the read brightness | luminance, and a divided image is displayed on each display module (step S09). At this time, the luminance of the light emitting elements 4 in the rightmost column of the display module 2-5 and the leftmost column of the display module 2-6 is higher than that when the divided image data is input. The luminance of the light emitting elements 4 in the uppermost row of the module 2-10 is corrected so as to be lower than that when the divided image data is input.

  As a result, when viewed as the entire screen of the image display device 3, the dark line generated at the joint portion between the display modules 2-5 and 2-6 is corrected so that the luminance of the light emitting element 4 near the joint is increased. Because it is inconspicuous. Further, the bright line generated at the joint portion between the display modules 2-7 and 2-10 is not conspicuous because the brightness of the light emitting element 4 in the vicinity of the joint is corrected to be low.

  As described above, according to the second embodiment of the present invention, as in the first embodiment, light emission in the vicinity of the joint is performed with respect to the display module 2 in which the installation deviation has occurred with a luminance correction value corresponding to the interval value of the joint. Since the luminance of the element is corrected, even when the interval of the seam varies depending on the set of the display modules 2, appropriate luminance correction is performed for each, and the seam portion of the entire image displayed on the image display device 3 is obtained. Can be made inconspicuous and image quality deterioration can be prevented.

  Further, when the interval value between the display modules 2 is narrower than that between the light emitting elements 4, luminance correction is performed so as to reduce the luminance of the light emitting elements 4 in the vicinity of the seams, so that the bright line at the seam portion is displayed. It is less noticeable and image quality deterioration can be prevented.

  Moreover, the brightness | luminance of the some pixel displayed on the light emitting element 4 in the both sides of the joint part between the display modules 2 can also be correct | amended, and the dark line or bright line which arises in a joint part can be made inconspicuous with sufficient balance.

Embodiment 3 FIG.
Embodiment 3 of the present invention will be described below with reference to the drawings. FIG. 16 is a configuration diagram of an image display system according to the third embodiment. FIG. 17 is a configuration diagram of a captured image analysis unit according to the third embodiment. FIG. 18 is a flowchart showing the calculation processing operation of the joint interval value according to the third embodiment. FIG. 19 is a diagram showing an image display device corresponding to captured image data according to the third embodiment in an orthogonal coordinate system. Portions corresponding to the configuration of the image display system according to the first embodiment are denoted by the same reference numerals as those in FIG.

  In the image display system according to the third embodiment, the image display device 3 in which the display module 2 is assembled is picked up by an image pickup device such as an external camera, and the control device 1 analyzes the picked-up image data so that the interval value of the seam is obtained. Is different from the first embodiment in that

  As illustrated in FIG. 16, when captured image data is input, the captured image analysis unit 15 provided in the control device 1 analyzes the input captured image data and displays between the display modules 2 in which the installation deviation occurs. The interval value of the joint is calculated and output to the luminance correction value output unit 12. As illustrated in FIG. 17, the captured image analysis unit 15 includes a captured image data input unit 150, an interval value calculation unit 151, and an installation deviation determination unit 152.

  The captured image data input unit 150 is an interface through which captured image data is input from the imaging device, and outputs the input captured image data to the interval value calculation unit 151.

  The interval value calculation unit 151 uses a captured image data output from the captured image data input unit 150, a first display module constituting the image display device 3 for captured image data, and a second adjacent to the first display module. The interval value of the joint between the display module and the interval value between the adjacent light emitting elements 4 in the display module 2 is calculated. Details of the calculation method will be described later.

  The installation deviation determination unit 152 compares the interval value between the seams between the display modules 2 calculated by the interval value calculation unit 151 and the interval value between the light emitting elements 4, and determines whether or not there is an installation deviation between the display modules 2. Determine whether. When it is determined that the installation deviation has occurred, the interval value of the joint between the display modules 2 and the display module number are output to the luminance correction value output unit 12. When it is determined that there is no installation deviation, a signal indicating that there is no installation deviation is output to the luminance correction value output unit 12.

  The operation of the interval value calculation process performed by the captured image data analysis unit 15 will be described with reference to FIGS.

  When the captured image data is input (step S001), the captured image data input unit 150 outputs the captured image data to the interval value calculation unit 151. The captured image data is an image display device 3 configured by arranging a plurality of display modules 2, and needs to be image data in a state where the light emitting elements 4 at the four corners of each display module 2 emit light. is there. Here, as shown in FIG. 19, the following description will be made using captured image data of the image display device 3 in which the display module 2 in which the plurality of light emitting elements 4 are arranged is arranged in N rows × N columns.

  The interval value calculation unit 151 performs a coordinate conversion process so that the vertical and horizontal directions of the image display device 3 of the input captured image data become horizontal and vertical, and analyzes the image data using the xy coordinates in the orthogonal coordinate system. The interval value between the light emitting elements 4 and the interval value between the display modules 2 are calculated.

  First, the interval value calculation unit 151 calculates an interval value between the light emitting elements 4 based on the xy coordinates of the light emitting elements 4 at the four corners in each display module 4 (step S002). As shown in FIG. 19, the coordinates (0,0) of the light emitting element 4 at the upper left corner of the display module 2-11 and the coordinates (c, 0) of the light emitting element 4 at the upper right corner of the display module 2-1N are marked. Then, the horizontal length c of the image display device 3 is calculated. Here, it is assumed that the value c is equal to the value of the horizontal length of the actual image display device 3.

  Next, when the length c is divided by the number obtained by subtracting 1 from the number of the light emitting elements 4 existing in one row of the image display device 3, the interval value between the light emitting elements 4 is obtained. For example, in the image display device 3 shown in FIG. 19, ten light emitting elements 4 are arranged in one row in one display module 2, and therefore exist in one row in the image display device 3. The number of light emitting elements 4 to be performed is 10N. Therefore, the interval value between the light emitting elements 4 is c / (10N-1). The same applies to the interval value between the light emitting elements 4 in the vertical direction.

  Returning to FIG. 18, the interval value calculation unit 151 next calculates the interval value of the joint between the display modules 2 (step S003). Here, using the coordinates (a, 0) of the light emitting element 4 at the upper right corner of the display module 2-11 and the coordinates (b, 0) of the light emitting element 4 at the upper left corner of the display module 2-12 as a mark, the display module. The interval value (ba) of the joint between 2-11 and 2-12 is calculated. The interval value calculation unit 151 calculates the calculated interval value c / (10N-1) between the light emitting elements 4 and the interval value (ba) of the joint between the display modules 2-11 and 2-12. Output to.

  The installation deviation determination unit 152 compares the interval value c / (10N-1) between the light emitting elements 4 with the interval value (ba) of the joint between the display modules 2-11 and 2-12, and displays the display module 2- 11 or 2-12 is determined whether or not there is a displacement (step S004).

  When both are the same value (step S005-Yes), the installation deviation determination unit 152 determines that there is no installation deviation between the display modules 2-11 and 2-12 (step S006).

  When both are not the same value (step S005-No), the installation deviation determination unit 152 determines that there is an installation deviation between the display modules 2-11 and 2-12 (step S007). Then, the installation deviation determination unit 152 outputs the joint interval value (b-a) between the display modules 2-11 and 2-12 to the luminance correction value output unit 12 (step S008).

  When the above processing for all the combinations of the display modules 2 is completed (step S009-Yes), the captured image data analysis unit 15 ends the calculation processing of the interval value between the display modules 2. If the above processing has not been completed for all the combinations of the display modules 2 (step S009-No), the captured image data analysis unit 15 applies to the display modules 2 different from the display modules 2-11 and 2-12. Thus, the processing from step S003 is repeated.

  As described above, the control device 1 performs the brightness correction setting process and the brightness correction process based on the interval value of the joint between the display modules 2 calculated by the captured image analysis unit 15. Since this is the same as the first embodiment, the description thereof is omitted.

  As described above, according to the third embodiment of the present invention, the captured image analysis unit 15 analyzes the captured image data of the image display device 3 captured by the imaging device, thereby displaying a display in which an installation shift has occurred. Since the interval value of the joint between the modules 2 is calculated, in addition to the effect of the first embodiment, the work load of the person in charge of installation can be greatly reduced. That is, it is not necessary for the person in charge of installation to measure the interval values of the joints between the display modules 2 one by one, and only the captured image data of the image display device 3 captured by the imaging device is output to the control device 1. Since the brightness correction setting process is automatically completed, the workload can be greatly reduced.

  Note that the control device 1 according to the second embodiment also has the same effect as that of the present embodiment by including the captured image analysis unit 15.

DESCRIPTION OF SYMBOLS 1 Control apparatus 11 Corresponding information storage part 12 Brightness correction value output part 13 Brightness correction part 14 Image division part 15 Captured image analysis part 150 Captured image data input part 151 Interval value calculation part 152 Installation deviation determination part 2 Display module 21 Light emission control part 22 brightness correction value storage unit 23 brightness correction unit 3 image display device 4 light emitting element

Claims (8)

A control device that corrects luminance of image data composed of a plurality of input pixels and outputs corrected image data, and a plurality of light emitting elements corresponding to the plurality of pixels of the image data are arranged and controlled A plurality of display modules to which the corrected image data from the device is input, and an image display device configured by arranging the plurality of display modules displays an image corresponding to the corrected image data An image display system,
The controller is
When the interval value between the first display module of the plurality of display modules and the second display module adjacent to the first display module is input, the input interval value corresponds to the input interval value. A brightness correction value output unit for outputting a brightness correction value for correcting the brightness of the plurality of pixels of the image data;
The brightness correction value output from the brightness correction value output unit is added to the brightness of each of the plurality of pixels, so that the first display module is adjacent to the second display module in the first display module. A luminance correction unit that corrects the luminance of the plurality of pixels on the line and on the second line adjacent to the first line in the second display module;
The brightness correction value output unit
Brightness correction values for correcting the plurality of pixels on the first line are alternately different values,
A brightness correction value for correcting the brightness of the plurality of pixels on the first line and a brightness of the pixels on the second line adjacent to the plurality of pixels on the first line are corrected. Outputting the brightness correction value so that the brightness correction value is a predetermined difference excluding 0 ;
A brightness correction value for correcting the brightness of the plurality of pixels on the first line is:
A value lower than the luminance correction value for correcting the luminance of the pixels on the adjacent second line and a value higher than the luminance correction value for correcting the luminance of the pixels on the adjacent second line. An image display system characterized by alternating values .   The luminance correction value output unit corresponds to the plurality of light emitting elements on the first line when the inputted interval value is larger than an interval value between the adjacent light emitting elements in the display module. Output a luminance correction value that increases the luminance of the plurality of pixels higher than the input luminance, and when the input interval value is smaller than the interval value between the adjacent light emitting elements in the display module, 2. The image display according to claim 1, wherein a luminance correction value that lowers luminance of the plurality of pixels corresponding to the plurality of light emitting elements on the first line is lower than luminance at the time of input. system. The brightness correction value output unit, when the input interval value is larger than the interval value between the adjacent light emitting elements, the plurality of pixels corresponding to the plurality of light emitting elements on the second line. Output a brightness correction value that makes the brightness of the input higher than the input brightness,
When the input interval value is smaller than the interval value between the adjacent light emitting elements, the luminance of the plurality of pixels corresponding to the plurality of light emitting elements on the second line is greater than the luminance at the time of input. The image display system according to claim 1, wherein a luminance correction value that lowers the output is output.   The control device calculates an interval value between the first display module and the second display module based on captured image data of the image display device captured by the imaging device, and outputs the brightness correction value The image display system according to claim 1, further comprising: a captured image analysis unit that outputs to the unit. The captured image analysis unit includes:
An interval value calculation unit that calculates an interval value between the first display module and the second display module and an interval value between the adjacent light emitting elements in the display module from the captured image data;
When the interval value between the display modules calculated by the interval value calculation unit is compared with the interval value between the light emitting elements to determine an installation error, and when it is determined that an installation error has occurred, the display module The image display system according to claim 4, further comprising an installation deviation determination unit that outputs an interval value therebetween to the luminance correction value output unit. The luminance of image data composed of a plurality of input pixels is corrected, and the corrected image data is output to a plurality of display modules in which a plurality of light emitting elements corresponding to the plurality of pixels of the image data are arranged. A control device for displaying an image corresponding to the corrected image data on an image display device configured by arranging the plurality of display modules,
When the interval value between the first display module of the plurality of display modules and the second display module adjacent to the first display module is input, the input interval value corresponds to the input interval value. A brightness correction value output unit for outputting a brightness correction value for correcting the brightness of the plurality of pixels of the image data;
The brightness correction value output from the brightness correction value output unit is added to the brightness of each of the plurality of pixels, so that the first display module is adjacent to the second display module in the first display module. A luminance correction unit that corrects the luminance of the plurality of pixels on the line and on the second line adjacent to the first line in the second display module;
The brightness correction value output unit
Brightness correction values for correcting the plurality of pixels on the first line are alternately different values,
A brightness correction value for correcting the brightness of the plurality of pixels on the first line and a brightness of the pixels on the second line adjacent to the plurality of pixels on the first line are corrected. Outputting the brightness correction value so that the brightness correction value is a predetermined difference excluding 0 ;
A brightness correction value for correcting the brightness of the plurality of pixels on the first line is:
A value lower than the luminance correction value for correcting the luminance of the pixels on the adjacent second line and a value higher than the luminance correction value for correcting the luminance of the pixels on the adjacent second line. A control device characterized by alternating values . A display module in which a plurality of light-emitting elements are arranged, and a plurality of light-emitting elements are arranged to form an image display device that displays an image.
A luminance correction value storage unit that stores a luminance correction value for correcting the luminance of a plurality of pixels constituting the input image data, corresponding to an interval value between adjacent display modules;
By adding the luminance correction values stored in the luminance correction value storage unit to the luminances of the plurality of pixels, a plurality of the pixels on the line adjacent to the adjacent display module among the plurality of pixels. A luminance correction unit for correcting the luminance of a plurality of pixels corresponding to the light emitting element,
The brightness correction value storage unit
Brightness correction values for correcting the plurality of pixels on the line are alternately different values,
The luminance correction values of the plurality of pixels on the line and the luminance correction values of the pixels on the adjacent line adjacent to the plurality of pixels on the line have a predetermined difference excluding 0. Store the brightness correction value ,
A brightness correction value for correcting the brightness of the plurality of pixels on the first line is:
A value lower than the luminance correction value for correcting the luminance of the pixels on the adjacent second line and a value higher than the luminance correction value for correcting the luminance of the pixels on the adjacent second line. A display module characterized by alternating values .   The luminance correction value stored in the luminance correction value storage unit is a plurality of the light emitting elements on the line when the interval value is larger than the interval value between the adjacent light emitting elements in the display module. If the interval value is smaller than the interval value between the adjacent light emitting elements in the display module, the plurality of pixels on the line The display module according to claim 7, wherein the display module has a value for lowering the luminance of the plurality of pixels corresponding to the light emitting element than that at the time of input.

Images