JP2019211632A - Display system, and display method - Google Patents

Abstract

To suppress an amount of consumption of a frame memory, and prevent an image shift between each display device by a simple circuit configuration in a display system that displays an image using a plurality of display devices.SOLUTION: In a display system 100, a display device 10a comprises: a signal processing unit 11a that generates a division image a; and a display unit 15a that displays the division image a. A display device 10d comprises: a signal processing unit 11d that generates a division image d; and a display unit 15d that displays the division image d. The signal processing unit 11a is configure to set a scan direction to a forward direction, and the signal processing unit 11d is configured to set the scan direction to an inverse direction. The signal processing unit 11a is configured to further set a delay time so that a timing when the display device 10a displays the division image a is in time for a timing when the display device 10d displays the division image d.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a display system and a display method for displaying an image using a plurality of display devices.

  Conventionally, a display system (also referred to as a multi-display system) that displays an image using a plurality of display devices (displays) arranged in a row direction and a column direction is known. In the display system, there is a technique for adjusting the scanning timing of each display device and adjusting the scanning direction of each display device so that the images displayed on each display device do not shift (image shift). Proposed.

  For example, in Patent Document 1, a plurality of control PCs that control a multi-display system are arranged in a plurality of rows so that the upper and lower sides in the scanning direction of the scanning lines are switched every other row from one image (one frame). A technique is disclosed in which a plurality of divided images to be displayed on each of the displays are generated, and each display PC displays the generated plurality of divided images on each display. Japanese Patent Application Laid-Open No. H10-260260 discloses that processing for rotating the image 180 degrees is performed on an image whose scanning direction is reversed (reverse scanning).

JP2013-117601A

  In the conventional technique, the control PC generates an image (divided image) to be displayed on each display from the video signal, and transmits the generated divided image to each display. For this reason, in the control PC, there is a problem that the amount of use of the frame memory increases and the circuit configuration becomes complicated.

  An object of the present invention is a display system that displays an image using a plurality of display devices, and can suppress image misalignment between the display devices with a simple circuit configuration while suppressing the amount of frame memory used. And providing a display method.

  In the display system according to one aspect of the present invention, a video signal corresponding to one frame is input to each of a plurality of display devices, and each of the plurality of display devices displays an image, thereby supporting the video signal. The display system for displaying an image of one frame, wherein the plurality of display devices include a first display device and a second display device arranged adjacent to each other in a first direction in which data signal lines extend. A first signal processing unit configured to generate a first divided image that is a part of the image based on a video signal in a first transmission period among the video signals corresponding to the one frame; A first display unit that displays the generated first divided image, wherein the second display device transmits a second transmission after the first transmission period of the video signal corresponding to the one frame. Based on the video signal of the period And a second signal processing unit that generates a second divided image that is a part of the image, and a second display unit that displays the generated second divided image, wherein the first signal processing unit includes: The scanning direction of the gate signal lines arranged in the first display device is set to the first scanning direction, and the second signal processing unit sets the scanning direction of the gate signal lines arranged in the second display device to The first scanning direction is set to a second scanning direction opposite to the first scanning direction, and the first signal processing unit further determines the timing at which the first display device displays the first divided image when the second display device The first delay time is set so as to match the timing for displaying the second divided image.

  According to another aspect of the present invention, a video signal corresponding to one frame is input to each of a plurality of display devices, and each of the plurality of display devices displays an image, thereby supporting the video signal. In the display method for displaying the image of one frame, the plurality of display devices include a first display device and a second display device arranged adjacent to each other in a first direction in which the data signal lines extend. A first signal processing step of generating a first divided image that is a part of the image based on a video signal in a first transmission period among the video signals corresponding to the one frame; A first display step of displaying the generated first divided image, wherein the second display device transmits a second transmission after the first transmission period of the video signal corresponding to the one frame. Period video signal A second signal processing step for generating a second divided image that is a part of the image based on the second signal display step for displaying the generated second divided image, wherein the first signal processing step includes: The scanning direction of the gate signal lines arranged in the first display device is set to the first scanning direction, and in the second signal processing step, the scanning direction of the gate signal lines arranged in the second display device is set as follows: The second scanning direction is set opposite to the first scanning direction, and the first signal processing step further determines the timing at which the first display device displays the first divided image is the second display direction. The first delay time is set so as to match the timing at which the apparatus displays the second divided image.

  ADVANTAGE OF THE INVENTION According to this invention, the display system which displays an image using a some display apparatus can prevent the image gap between each display apparatus with a simple circuit structure, suppressing the usage-amount of a frame memory.

FIG. 1 is a diagram showing a schematic configuration of a display system according to an embodiment of the present invention. FIG. 2 is a diagram showing data signal lines and gate signal lines arranged in the display device according to the embodiment of the present invention. FIG. 3 is a diagram schematically showing a scanning direction in the display device according to the embodiment of the present invention. FIG. 4 is a block diagram showing a specific configuration of the display system according to the embodiment of the present invention. FIG. 5 is a flowchart for explaining an example of the procedure of the delay time setting process in the display device according to the embodiment of the invention. FIG. 6 is a diagram illustrating an example of an image displayed in the display system according to the embodiment of the present invention. FIG. 7A is a diagram showing an example of an image displayed in the display system according to the comparative example, and FIGS. 7B and 7C are displayed in the display system according to the embodiment of the present invention. It is a figure which shows an example of an image. FIG. 8 is a diagram schematically showing the flow of processing until an image is displayed on the display surface of the display system according to the embodiment of the present invention. FIG. 9 is a timing chart showing display timings in the display device according to the embodiment of the present invention. FIG. 10 is a diagram showing another configuration of the display system according to the embodiment of the present invention. FIG. 11 is a diagram showing another configuration of the display system according to the embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the following embodiment is an example which actualized this invention, Comprising: It does not have the character which limits the technical scope of this invention.

  FIG. 1 is a diagram showing a schematic configuration of a display system 100 according to an embodiment of the present invention.

  The display system 100 includes a plurality of display devices 10 and a video output device 200. The plurality of display devices 10 are arranged side by side in the row direction and the column direction. The plurality of display devices 10 are daisy chain connected in a loop so that the video signal Dv is transmitted from upstream to downstream (see FIG. 2). In FIG. 1, four display devices 10a, 10b, 10c, and 10d are shown as an example. The number of display devices 10 is not limited. Hereinafter, the display system 100 will be described as including four display devices 10a, 10b, 10c, and 10d.

  When the display surface 110 of the display system 100 is a coordinate plane, the display device 10a is arranged at (row, column) = (1, 1), and the display device 10b is (row, column) = (1, 2). The display device 10c is arranged at (row, column) = (2, 2), and the display device 10d is arranged at (row, column) = (2, 1). FIG. 2 shows data signal lines DL (source lines) and gate signal lines GL (scanning signal lines) arranged in the display devices 10a, 10b, 10c, and 10d, respectively. Each of the display devices 10a, 10b, 10c, and 10d includes a plurality of data signal lines DL extending in the first direction (here, the column direction) and a plurality of data signal lines DL extending in the second direction (here, the row direction). Gate signal lines GL are arranged. Each of the display devices 10a, 10b, 10c, and 10d includes a plurality of thin film transistors (TFTs), pixel electrodes, and common electrodes (common electrodes) disposed in the vicinity of intersections of the data signal lines DL and the gate signal lines GL. , A liquid crystal layer and the like (both not shown) are included.

  The video output device 200 is configured by, for example, a personal computer, a television broadcast receiver, or an image playback device. The video output device 200 outputs an image to be displayed on the display surface 110 as a video signal Dv.

  The display system 100 displays the image of each frame corresponding to the video signal Dv on the display surface 110 configured by the display units of the four display devices 10a, 10b, 10c, and 10d. For example, when an image of one frame is divided into four areas, upper, lower, left and right, the display device 10a displays the upper left divided image in the upper left area (1, 1) of the display surface 110, and the display device 10b Are displayed in the upper right area (1, 2) of the display surface 110, and the display device 10c displays the lower right divided image in the lower right area (2, 2) of the display surface 110, and the display device 10d displays the lower left divided image in the lower left area (2, 1) of the display surface 110. Each divided image may have the same resolution or different resolutions.

  The display system 100 can set the scanning direction (scanning direction) of the gate signal line GL for each display device. FIG. 3 is a diagram schematically illustrating an example of the scanning direction of each of the display devices 10a, 10b, 10c, and 10d. In the case of the example shown in FIG. 3, the display devices 10a and 10b are set in the forward direction from top to bottom, and the display devices 10c and 10d are set in the reverse direction from bottom to top.

  The upper (upper left and upper right) divided images (an example of the first divided image of the present invention) correspond to, for example, the video signal in the first transmission period (for example, the first half period) of the video signal Dv corresponding to one frame. The lower (lower left and lower right) divided image (an example of the second divided image of the present invention) is a second transmission after the first transmission period of the video signal Dv corresponding to the one frame. It is an image corresponding to a video signal in a period (for example, the second half period).

  FIG. 4 is a block diagram showing a specific configuration of the display system 100 according to the embodiment of the present invention. The display devices 10a, 10b, 10c, and 10d are daisy chain connected in a loop so that the video signal Dv is transmitted from upstream to downstream.

  The display device 10a (an example of the first display device of the present invention) includes a signal processing unit 11a (an example of the first signal processing unit of the present invention), a frame memory 12a, a storage unit 13a, a drive control unit 14a, and a display unit 15a. (An example of the first display unit of the present invention). The video signal Dv output from the video output device 200 is input to the input terminal Tia of the display device 10a.

  The video output device 200 transmits an image (frame image) to be displayed on the display devices 10a, 10b, 10c, and 10d as the video signal Dv to the display device 10a. In FIG. 4, the video output device 200 shows the video signal Dv corresponding to the image of the first frame F1. In FIG. 4, reference signs “a” to “d” attached to the image of the first frame F <b> 1 indicate a part of the image (divided image). The divided image a represents an image displayed on the display device 10a, the divided image b represents an image displayed on the display device 10b, the divided image c represents an image displayed on the display device 10c, and the divided image d indicates an image displayed on the display device 10d.

  The video signal Dv input from the video output device 200 to the display device 10a is input to the signal processing unit 11a and transferred to the output terminal Toa of the display device 10a.

  The signal processing unit 11a stores the video signal Dv in the frame memory 12a. Specifically, the signal processing unit 11a sequentially transfers the video signal Dv received from the video output device 200 to the frame memory 12a. The frame memory 12a stores a video signal Dv (input image data) for one frame.

  In addition, the signal processing unit 11a performs various signal processes on the input image data. Specifically, the signal processing unit 11a cuts out data (divided image data) corresponding to the divided image a displayed by the display device 10a from the input image data of the frame memory 12a, and adds the divided image data described later to the divided image data. Each signal processing is performed to generate image data Da.

  For example, the signal processing unit 11a performs a process (image inversion process) for inverting the vertical direction of the divided image a displayed by the display device 10a on the divided image data. Specifically, the signal processing unit 11a performs the image inversion when the scanning direction of the gate signal line GL in the display device 10a (an example of the first scanning direction of the present invention) is set in the reverse direction from bottom to top. Process. For example, when the scanning direction is set in the reverse direction, the signal processing unit 11a reverses the reading direction when reading the divided image data from the frame memory 12a. The signal processing unit 11a performs the image inversion processing to generate image data Da. Note that the user of the display system 100 can perform an operation for setting the scanning direction (forward direction or reverse direction) on the setting screen.

  Further, for example, the signal processing unit 11a performs a process (enlarge process) for enlarging and displaying the divided image a (enlarged display) on the divided image data. Specifically, the signal processing unit 11a performs the enlargement process when a setting for enabling the enlarge display function is performed by the user. The signal processing unit 11a performs the enlargement process to generate image data Da. Note that the user of the display system 100 can perform an operation to enable or disable the large display function on the setting screen. The setting contents of the large display function are reflected in all the display devices 10a, 10b, 10c, and 10d. That is, when the user performs the setting for enabling the large display function, the large display function is enabled and the user disables the large display function in all the display devices 10a, 10b, 10c, and 10d. In this case, the large display function is disabled in all the display devices 10a, 10b, 10c, and 10d. For example, on the setting screen, the user sets the number of display devices 10 arranged in the horizontal direction, the number of display devices 10 arranged in the vertical direction, and the divided image to be displayed on each display device 10.

  The signal processing unit 11a may store the video signal Dv in the frame memory 12a after performing the enlargement process on the video signal Dv received from the video output device 200.

  For example, the signal processing unit 11a performs processing for adjusting display timing for the generated image data Da. Specifically, the signal processing unit 11a sets a delay time (an example of the first delay time of the present invention) for delaying the timing (display start timing) for outputting the image data Da to the display unit 15a (delay time). Setting process). The delay time is a time from when the display device 10a receives the video signal Dv until the display of the divided image a is started. The delay time setting process will be described later.

  The signal processing unit 11a transmits, to the drive control unit 14a, image data Da generated by performing the above-described signal processing (image inversion processing, enlargement processing, etc.) on the divided image data as necessary. Further, the signal processing unit 11a transmits delay time setting information (delay time setting information) set by the delay time setting process to the drive control unit 14a. The signal processing unit 11a may delay the timing for reading the divided image data from the frame memory 12a based on the set delay time. As described above, the delay processing based on the set delay time may be performed by the signal processing unit 11a, the drive control unit 14a, or another processing unit (not shown). Also good.

  Various setting information is stored in the storage unit 13a. For example, the storage unit 13 a stores information on the arrangement position ((row, column) = (1, 1)) of the display device 10 a with respect to the display surface 110 of the display system 100. The storage unit 13a stores setting information set by the user. For example, the storage unit 13a stores scanning direction setting information, large setting information, delay time setting information, and the like. The storage unit 13a stores a program for executing various processes (for example, delay time setting process).

  The drive control unit 14a controls driving of the display unit 15a. Specifically, the drive control unit 14a outputs the image data Da received from the signal processing unit 11a to the plurality of data signal lines DL while scanning the plurality of gate signal lines GL in the scanning direction set by the user. Then, the divided image a is displayed on the display unit 15a.

  The display unit 15a is configured by a liquid crystal panel, for example. The display unit 15 a displays the divided image a corresponding to the image data Da received from the drive control unit 14 a in the upper left area (1, 1) of the display surface 110 of the display system 100.

  The display device 10b (an example of the first display device of the present invention) includes a signal processing unit 11b (an example of the first signal processing unit of the present invention), a frame memory 12b, a storage unit 13b, a drive control unit 14b, and a display unit 15b. (An example of the first display unit of the present invention). The video signal Dv output from the video output device 200 and transferred from the display device 10a is input to the input terminal Tib of the display device 10b.

  The video signal Dv input from the display device 10a to the display device 10b is input to the signal processing unit 11b and transferred to the output terminal Tob of the display device 10b.

  The signal processing unit 11b stores the video signal Dv in the frame memory 12b. Specifically, the signal processing unit 11b sequentially transfers the video signal Dv received from the display device 10a to the frame memory 12b. The frame memory 12b stores a video signal Dv (input image data) for one frame.

  In addition, the signal processing unit 11b performs various signal processes on the input image data. Specifically, the signal processing unit 11b cuts data (divided image data) corresponding to the divided image b displayed on the display device 10b from the input image data of the frame memory 12b, and adds the divided image data to the divided image data described later. Each signal processing is performed to generate image data Db.

  For example, the signal processing unit 11b performs a process (image inversion process) for inverting the vertical direction of the divided image b displayed by the display device 10b on the divided image data. Specifically, the signal processing unit 11b performs the image inversion processing when the scanning direction of the gate signal line GL in the display device 10b (an example of the first scanning direction of the present invention) is set in the reverse direction. In the display device 10b, the scanning direction is set to be the same as the scanning direction of the display device 10a.

  In addition, for example, the signal processing unit 11b performs a process (enlarged display) for displaying the divided image b in an enlarged manner (enlarged display) with respect to the divided image data when the user performs the setting for enabling the large display function. Process). The signal processing unit 11b may store the video signal Dv in the frame memory 12b after performing the enlargement process on the video signal Dv received from the display device 10a.

  For example, the signal processing unit 11b performs a process for adjusting the display timing for the generated image data Db. Specifically, the signal processing unit 11b sets a delay time (an example of the first delay time of the present invention) for delaying the timing (display start timing) for outputting the image data Db to the display unit 15b (delay time). Setting process). In the display device 10b, the same delay time as that of the display device 10a is set. The delay time setting process will be described later.

  The signal processing unit 11b transmits the image data Db generated by performing the above-described signal processing (image inversion processing, enlargement processing, etc.) on the divided image data as necessary to the drive control unit 14b. In addition, the signal processing unit 11b transmits the delay time setting information (delay time setting information) set by the delay time setting process to the drive control unit 14b. The signal processing unit 11b may delay the timing for reading the divided image data from the frame memory 12b based on the set delay time. As described above, the delay processing based on the set delay time may be performed by the signal processing unit 11b, the drive control unit 14b, or another processing unit (not shown). Also good.

  Various setting information is stored in the storage unit 13b. For example, the storage unit 13b stores information on the arrangement position ((row, column) = (1, 2)) of the display device 10b with respect to the display surface 110 of the display system 100. In addition, setting information set by the user is stored in the storage unit 13b. For example, the storage unit 13b stores scanning direction setting information, large setting information, delay time setting information, and the like. The storage unit 13b stores a program for executing various processes (for example, delay time setting process).

  The drive control unit 14b controls driving of the display unit 15b. Specifically, the drive control unit 14b outputs the image data Db received from the signal processing unit 11b to the plurality of data signal lines DL while scanning the plurality of gate signal lines GL in the scanning direction set by the user. Then, the divided image b is displayed on the display unit 15b.

  The display unit 15b is configured by a liquid crystal panel, for example. The display unit 15b displays the divided image b corresponding to the image data Db received from the drive control unit 14b in the upper right area (1, 2) of the display surface 110 of the display system 100.

  The display device 10c (an example of the second display device of the present invention) includes a signal processing unit 11c (an example of the second signal processing unit of the present invention), a frame memory 12c, a storage unit 13c, a drive control unit 14c, and a display unit 15c. (An example of the second display unit of the present invention). The video signal Dv output from the video output device 200 and transferred from the display device 10b is input to the input terminal Tic of the display device 10c.

  The video signal Dv input from the display device 10b to the display device 10c is input to the signal processing unit 11c and transferred to the output terminal Toc of the display device 10c.

  The signal processing unit 11c stores the video signal Dv in the frame memory 12c. Specifically, the signal processing unit 11c sequentially transfers the video signal Dv received from the display device 10b to the frame memory 12c. The frame memory 12c stores a video signal Dv (input image data) for one frame.

  Further, the signal processing unit 11c performs various kinds of signal processing on the input image data. Specifically, the signal processing unit 11c cuts data (divided image data) corresponding to the divided image c displayed by the display device 10c from the input image data of the frame memory 12c, and adds the divided image data to the divided image data described later. Each signal processing is performed to generate image data Dc.

  For example, the signal processing unit 11c performs a process (image inversion process) for inverting the vertical direction of the divided image c displayed by the display device 10c on the divided image data. Specifically, the signal processing unit 11c performs the image inversion processing when the scanning direction of the gate signal line GL in the display device 10c (an example of the second scanning direction of the present invention) is set in the reverse direction. In the display device 10c, the scanning direction is set to be different (opposite) from the scanning direction of the display devices 10a and 10b.

  For example, the signal processing unit 11c performs a process (enlarged display) for displaying the divided image c in an enlarged manner (enlarged display) with respect to the divided image data when the user performs the setting for enabling the large display function. Process). The signal processing unit 11c may store the video signal Dv in the frame memory 12c after performing the enlargement process on the video signal Dv received from the display device 10b.

  For example, the signal processing unit 11c performs a process for adjusting the display timing for the generated image data Dc. Specifically, the signal processing unit 11c sets a delay time (an example of the second delay time of the present invention) for delaying the timing (display start timing) for outputting the image data Dc to the display unit 15c (delay time). Setting process). The delay time setting process will be described later.

  The signal processing unit 11c transmits, to the drive control unit 14c, image data Dc generated by performing the above-described signal processing (image inversion processing, enlargement processing, etc.) on the divided image data as necessary. Further, the signal processing unit 11c transmits the delay time setting information (delay time setting information) set by the delay time setting process to the drive control unit 14c. The signal processing unit 11c may delay the timing for reading the divided image data from the frame memory 12c based on the set delay time. As described above, the delay processing based on the set delay time may be performed by the signal processing unit 11c, the drive control unit 14c, or another processing unit (not shown). Also good.

  Various setting information is stored in the storage unit 13c. For example, the storage unit 13c stores information on the arrangement position ((row, column) = (2, 2)) of the display device 10c with respect to the display surface 110 of the display system 100. In addition, setting information set by the user is stored in the storage unit 13c. For example, the storage unit 13c stores scanning direction setting information, large setting information, delay time setting information, and the like. The storage unit 13c stores a program for executing various processes (for example, delay time setting process).

  The drive control unit 14c controls driving of the display unit 15c. Specifically, the drive control unit 14c outputs the image data Dc received from the signal processing unit 11c to the plurality of data signal lines DL while scanning the plurality of gate signal lines GL in the scanning direction set by the user. Then, the divided image c is displayed on the display unit 15c.

  The display unit 15c is configured by a liquid crystal panel, for example. The display unit 15 c displays the divided image c corresponding to the image data Dc received from the drive control unit 14 c in the lower right area (2, 2) of the display surface 110 of the display system 100.

  The display device 10d (an example of the second display device of the present invention) includes a signal processing unit 11d (an example of the second signal processing unit of the present invention), a frame memory 12d, a storage unit 13d, a drive control unit 14d, and a display unit 15d. (An example of the second display unit of the present invention). The video signal Dv output from the video output device 200 and transferred from the display device 10c is input to the input terminal Tid of the display device 10d.

  The video signal Dv input from the display device 10c to the display device 10d is input to the signal processing unit 11d.

  The signal processing unit 11d stores the video signal Dv in the frame memory 12d. Specifically, the signal processing unit 11d sequentially transfers the video signal Dv received from the display device 10d to the frame memory 12d. The frame memory 12d stores a video signal Dv (input image data) for one frame.

  In addition, the signal processing unit 11d performs various types of signal processing on the input image data. Specifically, the signal processing unit 11d cuts data (divided image data) corresponding to the divided image d displayed by the display device 10d from the input image data of the frame memory 12d, and adds the divided image data to the divided image data described later. Each signal processing is performed to generate image data Dd.

  For example, the signal processing unit 11d performs a process (image reversal process) for reversing the vertical direction of the divided image d displayed by the display device 10d on the divided image data. Specifically, the signal processing unit 11d performs the image inversion processing when the scanning direction of the gate signal line GL in the display device 10d (an example of the second scanning direction of the present invention) is set in the reverse direction. In the display device 10d, the scanning direction is set to be the same as the scanning direction of the display device 10c.

  Further, for example, the signal processing unit 11d performs a process (enlarged display) for enlarging and displaying the divided image d (enlarged display) with respect to the divided image data when the user performs the setting for enabling the large display function. Process). The signal processing unit 11d may store the video signal Dv in the frame memory 12d after performing the enlargement process on the video signal Dv received from the display device 10c.

  For example, the signal processing unit 11d performs a process for adjusting the display timing for the generated image data Dd. Specifically, the signal processing unit 11d sets a delay time (an example of the second delay time of the present invention) for delaying the timing (display start timing) for outputting the image data Dd to the display unit 15d (delay time). Setting process). In the display device 10d, the same delay time as that of the display device 10c is set. The delay time setting process will be described later.

  The signal processing unit 11d transmits the image data Dd generated by performing the above-described signal processing (image inversion processing, enlargement processing, etc.) on the divided image data as necessary to the drive control unit 14d. Further, the signal processing unit 11d transmits the delay time setting information (delay time setting information) set by the delay time setting process to the drive control unit 14d. The signal processing unit 11d may delay the timing for reading the divided image data from the frame memory 12d based on the set delay time. As described above, the delay processing based on the set delay time may be performed by the signal processing unit 11d, the drive control unit 14d, or another processing unit (not shown). Also good.

  Various setting information is stored in the storage unit 13d. For example, the storage unit 13d stores information on the position ((row, column) = (2, 1)) of the display device 10d with respect to the display surface 110 of the display system 100. In addition, setting information set by the user is stored in the storage unit 13d. For example, the storage unit 13d stores scanning direction setting information, large setting information, delay time setting information, and the like. The storage unit 13d stores a program for executing various processes (for example, delay time setting process).

  The drive control unit 14d controls driving of the display unit 15d. Specifically, the drive control unit 14d outputs the image data Dd received from the signal processing unit 11d to the plurality of data signal lines DL while scanning the plurality of gate signal lines GL in the scanning direction set by the user. Then, the divided image d is displayed on the display unit 15d.

  The display unit 15d is configured by a liquid crystal panel, for example. The display unit 15d displays the divided image d corresponding to the image data Dd received from the drive control unit 14d in the lower left area (2, 1) of the display surface 110 of the display system 100.

  The display system 100 or each display device 10 may set the scanning direction and the delay time in each display device 10 based on the arrangement information of each display device 10, or the user may set each display device on the setting screen. The scanning direction and the delay time in 10 may be set.

[Delay time setting process]
Hereinafter, an example of the procedure of the delay time setting process executed in each of the display devices 10a, 10b, 10c, and 10d will be described with reference to FIG. Here, on the setting screen, the user sets the scanning direction of the display devices 10a and 10b to the forward direction, sets the scanning direction of the display devices 10c and 10d to the reverse direction, and sets to enable the large display function. Suppose you have gone. Note that “S” shown in FIG. 5 indicates the step number of the processing procedure.

  First, the display device 10a determines whether or not the large function is set to be valid (S101). When the large function is set to be invalid (S101: NO), the process proceeds to S103. Here, since the large function is set to be valid (S101: YES), the process proceeds to S102.

  In S102, for example, the signal processing unit 11a sets a delay time for {(MN) / M} frames.

  Here, “M” in the above expression represents the number (number of rows) of the plurality of display devices 10 arranged in the first direction (here, the column direction) in the display system 100. Here, since the two display devices 10a and 10d are arranged side by side in the first direction, “M” = 2. In addition, “N” represents an arrangement position (row number) of the display device 10 for which a delay time is set in the display system 100. Here, since the display device 10a for which the delay time is set is arranged in the first row (first), “N” = 1.

  Thereby, in S102, the signal processing unit 11a sets a delay time for ½ frame.

  Next, the display device 10a determines whether or not the scanning direction is the reverse direction (S103). If the scanning direction is the reverse direction (S103: YES), the process proceeds to S104. If the scanning direction is the forward direction (S103: NO), the process proceeds to S105.

  In the display device 10a, since the scanning direction is set to the forward direction (S103: NO), the process proceeds to S105, and the signal processing unit 11a further adds one frame in addition to the delay time of ½ frame. Set the delay time. Therefore, in the display device 10a, the signal processing unit 11a sets a delay time (an example of the first delay time according to the present invention) for a total of 1.5 frames. Accordingly, the display device 10a starts displaying the divided image a corresponding to the image data Da 1.5 frames after the display device 10a receives the video signal Dv.

  In the display device 10b, the same processing as that of the display device 10a is performed. Accordingly, the display device 10b starts displaying the divided image b corresponding to the image data Db 1.5 frames after the video signal Dv is input to the display device 10b.

  In the display device 10c, since the large function is set to be effective (S101: YES), the signal processing unit 11c sets a delay time for {(MN) / M} frames (S102). Here, since the display device 10c is arranged in the second row (second), “N” = 2. For this reason, in S102, the signal processing unit 11c sets the delay time to “0”.

  Next, in the display device 10c, since the scanning direction is set in the reverse direction (S103: YES), the signal processing unit 11c performs image inversion processing. Specifically, the signal processing unit 11c reverses the reading direction when reading the divided image data corresponding to the divided image c from the frame memory 12c. Therefore, in the display device 10c, the signal processing unit 11c sets the delay time to “0”. Thus, after the video signal Dv for one frame is input to the display device 10c, the display device 10c performs the image inversion processing without performing the delay processing, and the divided image c of the divided image c corresponding to the image data Dc. Start display.

  In the display device 10d, processing similar to that of the display device 10c is performed. Thus, after the video signal Dv is input to the display device 10d, the display device 10d performs the image inversion processing without performing delay processing, and starts displaying the divided image d corresponding to the image data Dd. . As described above, the signal processing units 11a and 11b delay the display devices 10a and 10b so that the timings at which the display devices 10a and 10b display the divided images a and b match the timings at which the display devices 10c and 10d display the divided images c and d. Set the time.

[Display processing]
Hereinafter, an example of an image displayed on the display surface 110 of the display system 100 by the display process executed based on the delay time set by the delay time setting process will be described with reference to FIGS. 6 and 7. . Here, it is assumed that the image corresponding to the video signal Dv is an image in which a vertical line extending in the column direction moves to the right as shown in FIG. In FIG. 7, for convenience, an image displayed on the display device 10 a arranged at (row, column) = (1, 1) and a display device 10 c arranged at (row, column) = (2, 1) are shown. The displayed image is shown.

  FIG. 7A shows an image displayed in the display system according to the comparative example, and FIGS. 7B and 7C show images displayed in the display system 100 according to the embodiment of the present invention. Show. FIG. 7A shows a case where the scanning directions of the display devices 10a, 10b, 10c, and 10d in the first row and the second row are set to the forward direction. FIG. 7B shows a case where the scanning direction of the first row display devices 10a and 10b is set to the forward direction, and the scanning direction of the second row display devices 10c and 10d is set to the reverse direction. FIG. 7C shows a case where the scanning direction of the display devices 10a and 10b in the first row is set in the reverse direction and the scanning direction of the display devices 10c and 10d in the second row is set in the forward direction.

  First, an image displayed in the display system according to the comparative example will be described with reference to FIG.

  When the first frame starts, the display devices 10a and 10d start to receive the video signal Dv, and the display device 10a starts displaying the divided image a of the first frame image (see FIG. 6). When the half frame has elapsed, the display device 10d starts receiving the video signal Dv corresponding to the divided image d of the first frame displayed by the display device 10d out of the video signal Dv, and displays the divided image d. To start.

  When the second frame starts, the display device 10a starts displaying the divided image a of the second frame image (see FIG. 6). When the half frame has elapsed, the display device 10d starts to receive the video signal Dv corresponding to the divided image d of the second frame displayed by the display device 10d in the recorded video signal Dv, and displays the divided image d. To start.

  By performing display processing in this way, in the display system according to the comparative example, each image (divided image a,) displayed on the display devices 10a and 10d arranged in the first direction (here, the column direction). c) A shift (image shift) occurs.

  Next, an image displayed on the display system 100 according to the embodiment of the present invention will be described with reference to FIG. In FIG. 7B and FIG. 7C, the processing time and delay time corresponding to the image inversion processing are omitted. The display process of the display system 100 is included in the display method according to the present invention. The display method according to the present invention also includes a signal processing step including a step of setting a scanning direction, a step of generating a divided image, and a step of setting a delay time (first signal processing step, second signal processing according to the present invention). And a display step (corresponding to the first display step and the second display step according to the present invention) for displaying the generated divided image.

  When the first frame starts, the display devices 10a and 10d start to receive the video signal Dv, and the display device 10a has a delay time (here, 1) set in the delay time setting process (see S102 in FIG. 5). Display of the divided image a of the image of the first frame (see FIG. 6) is started. When 1/2 frame has elapsed since the start of reception of the video signal Dv, the display device 10d receives the video signal Dv corresponding to the divided image d of the first frame displayed by the display device 10d of the video signal Dv. The display of the divided image d is started.

  Even when the scanning direction of the display devices 10a and 10d is set to the scanning direction shown in FIG. 7C, the display processing is the same as that in FIG. 7B. When the first frame starts, the display devices 10a and 10d start receiving the video signal Dv, and the display device 10a receives the delay time (1/2 frame) set in the delay time setting process (see S102 in FIG. 5). Minutes), the display of the divided image a of the first frame image (see FIG. 6) is started. When 1/2 frame has elapsed since the start of reception of the video signal Dv, the display device 10d receives the video signal Dv corresponding to the divided image d of the first frame displayed by the display device 10d of the video signal Dv. The display of the divided image d is started.

  FIG. 8 is a diagram schematically showing the flow of processing until an image is displayed on the display surface 110 of the display system 100. Here, a case where three display devices 10a, 10b, and 10c are arranged in the first direction (column direction) will be described as an example. The display device 10a displays the upper divided image a in the image of the first frame F1 corresponding to the video signal Dv, the display device 10b displays the middle divided image b in the image, and the display device 10c The lower divided image c of the images is displayed. The display devices 10a, 10b, and 10c execute an enlargement process for enlarging the divided images a, b, and c to a size corresponding to the display devices 10a, 10b, and 10c. Here, since the scanning directions of the display devices 10a and 10c are set in the reverse direction, the display devices 10a and 10c execute the image inversion process.

  In the example shown in FIG. 8, the display device 10a sets a delay time for {(3-1) / 3} = 2/3 frames, and the display device 10b uses {(2-1) / 3} = The delay time for (1 + 1/3) frames, which is a sum of the 1/3 frame and one frame associated with the image inversion process, is set, and the display device 10c sets the delay time to “0”. The display devices 10a, 10b, and 10c start displaying the divided images a, b, and c at timings corresponding to the delay times, respectively.

  According to the display system 100 according to the embodiment of the present invention, a shift between the images (the divided images a and c) displayed on the display devices 10a and 10d arranged in the first direction (here, the column direction) ( Image misalignment) can be eliminated. Further, since the video output device 200 is configured to output the video signal Dv corresponding to an image of one frame without generating an image (divided image) corresponding to each display device 10, the usage amount of the frame memory is reduced. There is no increase. Therefore, image shift between the display devices can be prevented with a simple circuit configuration while suppressing the amount of frame memory used. When the image inversion process is performed, the display system 100 delays the display start timing of the image on the display device 10 in which the scanning direction is set to the forward direction by one frame (see S105 in FIG. 5).

  FIG. 9 is a timing chart showing display timing in each of the display devices 10a, 10b, 10c, and 10d. In the above example, as shown in FIG. 9, the display devices 10a and 10b start displaying the divided images a and b corresponding to the image data Da, respectively, 1.5 frames after receiving the video signal Dv. To do. In addition, the display devices 10c and 10d, when 1/2 frame has elapsed from the start of reception of the video signal Dv, respectively, the divided image c and the first frame of the video signal Dv displayed by the display devices 10c and 10d. Reception of the video signal Dv corresponding to d is started, and after the image inversion processing is performed thereafter, display of the divided images c and d is started.

  As described above, in the delay time setting process, the number of display devices 10 arranged in the first direction (number of rows) and the arrangement position (row number) of the display device 10 for which the delay time is set are based. Delay time is set. For example, when three display devices 10 are arranged in the first direction, the delay time for {(3-1) / 3} = 2/3 frames is set in the display device 10 in the first row. In the display device 10 in the second row, a delay time of {(2-1) / 3} = 1/3 frame is set. Similarly, for example, when four display devices 10 are arranged in the first direction, the delay time for {(4-1) / 4} = 3/4 frames is set in the display device 10 in the first row. In the display device 10 in the second row, a delay time of {(4-2) / 4} = 2/4 frames is set, and in the display device 10 in the third row, {(4-3) / 4 } = Delay time for 1/4 frame is set.

  The display system 100 according to the present invention is not limited to the above-described configuration. For example, the display system 100 may omit the enlargement process (image enlargement process), and each display device 10 may display a part of the image (divided image) at an equal magnification without enlargement. In this configuration, in step S101 shown in FIG. 5, it is determined whether or not the video signal Dv input from the video output device 200 is a divided image, and when it is not a divided image (that is, a frame image), In step S102, a process for setting a delay time may be performed.

  In the display system 100 described above, a plurality of display devices 10 are daisy chain connected, and the video signal Dv output from the video output device 200 is input to the display device 10a. It is not limited to. For example, each of the plurality of display devices 10 may be connected to the video output device 200, and the video signal Dv output from the video output device 200 may be input to each display device 10.

  In the display system 100, in each display device 10, the gate signal lines GL may be arranged to extend in the column direction, and the data signal lines DL may be arranged to extend in the row direction.

  In the display system 100 described above, in each display device 10, the data signal lines DL are arranged so as to extend in the column direction (vertical), and the gate signal lines GL are arranged so as to extend in the row direction (horizontal). The so-called horizontal type is also used. As another embodiment, in the display system 100, in each display device 10, the data signal lines DL are arranged so as to extend in the row direction (horizontal), and the gate signal lines GL extend in the column direction (vertical). It may be configured as a so-called vertical type arranged as described above. In the vertically-arranged configuration, for example, when the display device 10d (an example of the second display device of the present invention) is arranged on the right side of the display device 10a (an example of the first display device of the present invention), the display device The scanning direction of the gate signal line GL in 10a (an example of the first scanning direction of the present invention) is set to the direction from right to left, and the scanning direction of the gate signal line GL in the display device 10d (second scanning direction of the present invention). Is set in a direction from left to right (see FIG. 10), the signal processing unit 11a performs image inversion processing for inverting the left-right direction of the divided image a. On the other hand, when the scanning direction of the gate signal line GL in the display device 10a is set to the direction from left to right, and the scanning direction of the gate signal line GL in the display device 10d is set to the direction from right to left (see FIG. 11), the signal processing unit 11d performs image inversion processing for inverting the left-right direction of the divided image d.

10: Display devices 10a to 10d: Display devices 11a to 11d: Signal processing units 12a to 12d: Frame memories 13a to 13d: Storage units 14a to 14d: Drive control units 15a to 15d: Display unit 100: Display system 110: Display surface 200: Video output devices Da to Dd: Image data Dv: Video signals a to d: Divided images

Claims (9)

A display system in which a video signal corresponding to one frame is input to each of a plurality of display devices, and each of the plurality of display devices displays an image, thereby displaying the image of the one frame corresponding to the video signal. There,
The plurality of display devices include a first display device and a second display device arranged adjacent to each other in a first direction in which the data signal lines extend,
A first signal processing unit configured to generate a first divided image that is a part of the image based on a video signal in a first transmission period of the video signal corresponding to the one frame; A first display unit that displays the first divided image,
The second display device generates a second divided image that is a part of the image based on a video signal in a second transmission period after the first transmission period among the video signals corresponding to the one frame. A second signal processing unit, and a second display unit for displaying the generated second divided image,
The first signal processing unit sets a scanning direction of a gate signal line disposed in the first display device to a first scanning direction;
The second signal processing unit sets a scanning direction of a gate signal line disposed in the second display device to a second scanning direction opposite to the first scanning direction;
The first signal processing unit further includes a first delay so that a timing at which the first display device displays the first divided image matches a timing at which the second display device displays the second divided image. Set the time,
Display system. The first delay time is a time from when the first display device receives the video signal until the display of the first divided image starts.
The display system according to claim 1. The plurality of display devices include M display devices arranged side by side in the first direction,
The signal processing unit of the display device arranged in the Nth direction in the first direction sets a delay time corresponding to {(MN) / M} frames included in the first delay time.
The display system according to claim 1 or 2. In the case where the second display device is disposed adjacently under the first display device,
When the first scanning direction is set in a direction from bottom to top and the second scanning direction is set in a direction from top to bottom, the first signal processing unit further includes the first divided image. While performing image inversion processing to invert the vertical direction of
When the first scanning direction is set in a direction from top to bottom and the second scanning direction is set in a direction from bottom to top, the second signal processing unit further includes the second divided image. Perform image inversion processing to invert the vertical direction of
The display system according to claim 3. In the case where the second display device is disposed adjacent to the right of the first display device,
When the first scanning direction is set in a direction from right to left and the second scanning direction is set in a direction from left to right, the first signal processing unit further includes the first divided image. While performing image inversion processing to invert the left and right direction of
When the first scanning direction is set to a direction from left to right and the second scanning direction is set to a direction from right to left, the second signal processing unit further includes the second divided image. Perform image inversion processing to invert the left and right direction of
The display system according to claim 3. When the first signal processing unit performs the image inversion processing, the second signal processing unit sets a delay time for one frame included in the first delay time,
When the second signal processing unit performs the image inversion processing, the first signal processing unit sets a delay time for one frame included in the first delay time.
The display system according to claim 4 or 5. The first signal processing unit performs processing for enlarging and displaying the first divided image, and the second signal processing unit performs processing for enlarging and displaying the second divided image.
The display system according to any one of claims 1 to 6. A video output device for outputting the video signal;
The plurality of display devices are daisy chain connected in a loop so that the video signal is transmitted from upstream to downstream,
The display system according to any one of claims 1 to 7. A display method in which a video signal corresponding to one frame is input to each of a plurality of display devices, and each of the plurality of display devices displays an image, thereby displaying the image of the one frame corresponding to the video signal. There,
The plurality of display devices include a first display device and a second display device arranged adjacent to each other in a first direction in which the data signal lines extend,
A first signal processing step of generating a first divided image that is a part of the image based on a video signal in a first transmission period of the video signal corresponding to the one frame; A first display step for displaying the first divided image,
The second display device generates a second divided image that is a part of the image based on a video signal in a second transmission period after the first transmission period among the video signals corresponding to the one frame. A second signal processing step, and a second display step for displaying the generated second divided image,
In the first signal processing step, the scanning direction of the gate signal line arranged in the first display device is set to the first scanning direction,
In the second signal processing step, a scanning direction of the gate signal line arranged in the second display device is set to a second scanning direction opposite to the first scanning direction,
In the first signal processing step, a first delay is further performed so that the timing at which the first display device displays the first divided image matches the timing at which the second display device displays the second divided image. Set the time,
Display method.

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