JP2018037765A - Video signal processing device - Google Patents

Abstract

A video signal processing device receives a plurality of video signals indicating divided videos from a plurality of video signal sources and generates video signals for appropriately arranging the plurality of divided videos and displaying them on a video display device. do. A video signal processing device (100) is a device for receiving a plurality of video signals and generating video signals to be displayed on a display area composed of a plurality of display devices. and a group determination unit (130) for grouping a plurality of video signals based on information included in the video signals. [Selection drawing] Fig. 1

Description

  The present disclosure relates to a video signal processing apparatus that inputs a plurality of video signals, arranges and outputs a video indicated by the input video signals.

  In recent years, multi-display devices that connect a plurality of video display devices and function as a single display have become widespread. Such a multi-display device is highly convenient because the number of video display devices to be connected can be freely increased / decreased in accordance with the environment of the installation place, the application, and the purpose. For this reason, multi-display devices are often used mainly for business purposes such as exhibitions that require large screens, stadiums, building walls, and concerts.

  Since the multi-display device can display a large screen image, it is suitable for displaying a plurality of images simultaneously. For example, according to the multi-display device, images from a plurality of video signal sources such as a camera and a video can be simultaneously input and displayed in a desired arrangement.

  In order to realize such a display, generally, a desired video is selected from a plurality of input videos and displayed in various sizes and arrangements between a plurality of video signal sources and a plurality of video display devices. A multi-window processing device is inserted.

  In recent years, with regard to individual images to be input, high-resolution images such as 4K × 2K (3840 pixels × 2160 pixels or 4096 pixels × 2160 pixels), which is four times as high as full high-definition (1920 pixels × 1080 pixels), and 8K × 4K The use of is increasing. Such a high-resolution video cannot be transmitted through a single signal line due to transmission band restrictions, and may be transmitted through a plurality of signal lines. In such a case, a video signal of a part of the video generated by dividing the entire video is transmitted through each signal line.

  As a result, video signals from a plurality of video signal sources are input to the multi-window device as videos further divided into a plurality of areas. In such a case, since the signal source of the video signal cannot be distinguished in the multi-window processing device, video grouping and arrangement processing is required by the manual operation of the operator.

  Patent Document 1 discloses an image display device that displays a plurality of input videos side by side on a display panel screen. In Patent Document 1, in order to determine the arrangement of a plurality of videos, the difference value of the pixel values at the edges of the adjacent video is calculated for all the arrangement candidates, and the candidate of which the sum of the difference values is the smallest is calculated. Display multiple videos by arrangement.

JP 2012-173424 A

  In Patent Document 1, it is possible to determine only about images from the same video signal source, and it is not possible to determine the arrangement when videos from different video signal sources are mixed.

  The present disclosure relates to a video signal processing device that receives a plurality of video signals indicating divided videos from a plurality of video signal sources, and generates a video signal for appropriately arranging the plurality of divided videos to be displayed on a video display device. provide.

  In a first aspect of the present disclosure, there is provided a video signal processing device that receives a plurality of video signals and generates a video signal for display on a display area including a plurality of display devices. The video signal processing apparatus includes an input unit that inputs a plurality of video signals, and a group determination unit that groups the plurality of video signals based on information included in the video signals.

  According to the video signal processing device of the present disclosure, a plurality of video signals are grouped based on the characteristics of the video signal. By grouping the video signals in this way, the video signals in the group can then be automatically or manually arranged as signals from the same video signal source. As a result, when receiving a plurality of video signals indicating the divided video from a plurality of video signal sources, the original video before the division can be appropriately reconstructed.

1 is a diagram illustrating a configuration of a video display system including a video signal processing device (multi-window processing device (MWP)) according to a first embodiment of the present disclosure. The figure which shows the example of the combination of the video signal input into a multiwindow processing apparatus from several video signal sources The figure which showed the example of the display screen of the controller which comprises a video display system The figure which shows the specific structure of a multi-window processing apparatus (MWP). The figure which shows the concrete structure of the synchronizing signal detection part in a multiwindow processing apparatus. (A) A diagram showing a clock signal (CLK), (B) a diagram showing a synchronizing signal (vertical synchronizing signal V1_sync) of a video signal inputted via the input terminal 1, (C) an input terminal n (n = 2,. .., 16) A diagram showing a synchronizing signal (vertical synchronizing signal Vn_sync) of a video signal inputted via 16) The figure which shows the specific structure of the correlation detection part in a multi-window processing apparatus. The figure explaining the peripheral part of a picture The figure for explaining the calculation method of the correlation value between images The figure explaining the flow of processing in a multi-window processing device The flowchart which shows the group determination process by the group determination part of MWP The flowchart which shows the arrangement | positioning determination process by the arrangement | positioning determination part of MWP The figure explaining the arrangement pattern candidate of four images The figure for demonstrating the calculation method of the average of the correlation value between the images | videos regarding the arrangement | positioning pattern of four images | videos The figure for demonstrating the arrangement | positioning method of the image | video in Embodiment 2 of this indication. The figure for demonstrating the arrangement | positioning method of the image | video in Embodiment 2 of this indication. The figure for demonstrating the arrangement | positioning method of the image | video in Embodiment 2 of this indication. The figure which showed another structural example of MWP in other embodiment of this indication

Hereinafter, embodiments will be described in detail with reference to the drawings as appropriate. However, more detailed description than necessary may be omitted. For example, detailed descriptions of already well-known matters and repeated descriptions for substantially the same configuration may be omitted. This is to avoid the following description from becoming unnecessarily redundant and to facilitate understanding by those skilled in the art.
The inventor (s) provides the accompanying drawings and the following description in order for those skilled in the art to fully understand the present disclosure, and is intended to limit the subject matter described in the claims. Not what you want.

(Embodiment 1)
[1-1. Constitution]
FIG. 1 is a diagram illustrating a configuration example of a video display system including a multi-window processing device which is an example of a video signal processing device.

  The video display system includes a multi-display 10 that displays video, a multi-window processing device (hereinafter referred to as “MWP”) 100 that receives video signals from a plurality of video signal sources and generates video signals to be displayed on the multi-display 10. And a controller 200 that gives an instruction to the MWP 100 according to a user operation.

  The multi display 10 includes a plurality of video display devices, and the plurality of video display devices are combined to function as one display device. In the example of FIG. 1, the multi-display 10 is composed of four video display devices. Each video display device is a liquid crystal display, an organic EL display, or a projector.

  The MWP 100 inputs a plurality of video signals from a plurality of video signal sources, generates a video signal to be displayed on each video display device constituting the multi-display 10, and outputs the video signal to each video display device. A video signal is sent from one video signal source to the MWP 100 via one or a plurality of signal lines. For this reason, the MWP 100 includes a plurality of input terminals (16 terminals in the example of FIG. 1).

  In the example of FIG. 1, video signals are input to the MWP 100 from six video signal sources A to F. The resolution of the video signal from each of the video signal sources A to F, the number of signal lines, and the resolution per signal line are as shown in FIG. One signal line is connected to the MFP 100 from each of the video signal sources A, C, and F. Four signal lines are connected to MFP 100 from video signal sources B, D, and E, respectively. That is, from the video signal sources B, D, and E, the original video of each video signal source is divided into four videos, and the video signal indicating each divided video is divided through four signal lines. Is transmitted. In FIG. 1, a total of 15 signal lines are connected to the MWP 100.

  The MWP 100 includes a plurality (16 in this embodiment) of output terminals. In FIG. 1, since the multi-display 10 is composed of four displays, the MWP 100 sends video signals to the multi-display 10 via four output terminals, that is, four signal lines.

  A controller 200 is connected to the MWP 100. The controller 200 is constituted by a personal computer, for example. The controller 200 is connected to the MWP 100. The controller 200 includes a display unit that displays a display screen showing a connection status of a plurality of video signals and a video display status in the MFP 100. FIG. 3 shows an example of the display screen of the controller 200. Display screen 220 displays the connection status of each input terminal of MFP 100. On the display screen, a plurality of input terminals are grouped, and input terminals of the same group are displayed surrounded by a broken-line frame. The MFP 100 has a function of grouping video signals (input terminals) that are considered to be signals from the same video signal source based on video signals input from the respective input terminals.

  For example, as shown in FIG. 1, the input terminal 1 is connected to a signal line from the video signal source A. Input terminals 2 to 5 are connected to signal lines from the video signal source B. The input terminal 6 is connected to a signal line from the video signal source C. Input terminals 7 to 9 and 11 are connected to signal lines from the video signal source D. Input terminals 10, 12, 13, and 15 are connected to a signal line from the video signal source E. The input terminal 14 is connected to a signal line from the video signal source F. In such a case, the MWP 100 groups video signal lines based on each video signal. The controller 200 receives information about grouping from the MWP 100, and as shown in FIG. 3, the input terminals 2 to 5 are set as one group, the input terminals 7 to 9 and 11 are set as another group, and the input terminals 10, 12, 13 and 15 are displayed on the display screen 220 as another group surrounded by a broken line frame.

  In addition, when the signal lines from the video signal sources are not sequentially connected to the input terminals, the controller 200 displays the input terminals by appropriately replacing the numbers of the input terminals. For example, as shown in FIG. 1, one of the signal lines from the video signal source D is connected to the input terminal 11, while one of the signal lines from the video signal source E is connected to the input terminal 10. . One of the signal lines from the video signal source E is connected to the input terminal 15, while one of the signal lines from the video signal source F is connected to the input terminal 14. At this time, with respect to the input terminals 10 and 11, the order of the input terminals to which the signal line from the video signal source D and the signal line from the video signal source E are connected is reversed. Further, regarding the input terminals 14 and 15, the order of the input terminals to which the signal line from the video signal source E and the signal line from the video signal source F are connected is reversed. For this reason, as shown in FIG. 3, on the display screen 220, “10” and “11” and “14” and “15” are exchanged for the input terminal numbers.

  Further, on the display screen 220, a button 222 for selecting whether or not to display the grouped video signals on the multi-display 10 is displayed. In the example of FIG. 3, the input terminal 1 and the input terminals 10, 12, 13, and 15 are selected, so that the video signal source A and the video from the video signal source E are displayed. On the screen 220 of the controller 200, a preview image 224 of the image displayed on the multi-display 10 is displayed.

  The user can perform operations such as selecting a video to be displayed on the multi-display 10, changing the video size, adjusting the arrangement, and the like by operating on the screen while viewing the video on the display screen 220 of the controller 200. For example, in FIG. 3, the size and arrangement of the video of the video signal source A and the video of the video signal source E are adjusted according to the user operation (designation). At this time, the video from the video signal source A and the video from the video signal source E arranged like the preview video 224 are displayed by the four video display devices constituting the multi-display 10.

[1-2. Multi-window processing device (MWP)]
A specific configuration of the MWP 100 will be described. FIG. 4 is a block diagram showing the overall configuration of the MWP 100. The MWP 100 includes 16 video signal input units 110, 16 synchronization signal detection units 120, a group determination unit 130, 16 correlation detection units 140, an arrangement determination unit 150, an operation unit 160, A window processing unit 170 and a video dividing unit 180 are provided.

  The video signal input unit 110 is provided for each input terminal, and inputs a video signal from a signal line connected to the input terminal. That is, in this embodiment, 16 video signal input units 110 are provided.

  The synchronization signal detection unit 120 receives a video signal from each video signal input unit 110, extracts a synchronization signal (in this case, a vertical synchronization signal V_sync) of the video signal from each signal line, and outputs a synchronization signal between the video signals. Are compared with each other and the comparison results are output. Details of the configuration and operation of the synchronization signal detection unit 120 will be described later.

  The group determination unit 130 determines a group for each of the plurality of video signals based on the comparison results of the phase comparison unit 127 and the period comparison unit 125. That is, the group determination unit 130 groups a plurality of video signals. Details of the configuration and operation of the group determination unit 130 will be described later.

  The correlation detector 140 calculates a correlation value between the video signals. The layout determination unit 150 determines the video layout based on the correlation value calculated by the correlation detection unit 140.

  The multi-window processing unit 170 arranges the video signal input from the video signal input unit 110 according to the arrangement determined by the arrangement determination unit 150.

  The video dividing unit 180 receives the video signal from the multi-window processing unit 170, divides the video indicated by the received video signal in accordance with the number of video display devices constituting the multi-display 10, and generates a video for each video display device. Generate and output a signal.

  The operation unit 160 is a means for accepting user instructions, and includes various input means such as buttons, dials, switches, a keyboard, a mouse, and a touch panel. Further, the MWP 100 may accept a user instruction via the controller 200.

  In the MWP 100, the functions of the video signal input unit 110, the synchronization signal detection unit 120, the group determination unit 130, the correlation detection unit 140, the arrangement determination unit 150, the multi-window processing unit 170, and the video division unit 180 are executed by the CPU. May be realized. The functions of these processing units may be realized by a dedicated electronic circuit. That is, the MWP 100 can be configured by various devices such as a CPU, MPU, GPU, DSP, FPGA, ASIC, and the like.

(Synchronous signal detector)
FIG. 5 is a diagram illustrating a configuration of the synchronization signal detection unit 120 in the MWP 100. The synchronization signal detection unit 120 includes a synchronization signal acquisition unit 121, a counter 122, a phase calculation unit 123, a phase comparison unit 127, a cycle calculation unit 124, a cycle comparison unit 125, and a group determination unit 130. The synchronization signal acquisition unit 121, the counter 122, and the cycle calculation unit 124 are provided for each signal line, that is, for each input terminal.

  The synchronization signal acquisition unit 121 extracts a synchronization signal (vertical synchronization signal V_sync) from the video signal. For example, synchronization signals as shown in FIGS. 6B and 6C are extracted. Here, FIG. 6B shows a synchronizing signal (vertical synchronizing signal V1_sync) of the video signal input via the input terminal 1. FIG. FIG. 6C shows a synchronizing signal (vertical synchronizing signal Vn_sync) of the video signal inputted through the input terminal n (n = 2, 3,..., 16).

  The counter 122 counts the synchronization signal interval (T1, Tn) (n = 2, 3,..., 16) based on the clock signal (CLK) as shown in FIG. The phase calculation unit 123 obtains the phase of the synchronization signal of each video signal (rise timing of the synchronization signal V_sync) based on the count value of the counter 122.

  The phase comparison unit 127 compares the phase of the synchronization signal between the video signals. Specifically, the phase comparison unit 127 compares the phase of the synchronization signal between the reference video signal (for example, the video signal input via the input terminal 1) and another video signal, It is determined whether or not. More specifically, a phase difference ΔPn is obtained between a reference video signal (for example, a video signal input via the input terminal 1) and another video signal, and ΔPn is equal to or less than a predetermined value. , It is determined that the phases match.

  The period calculation unit 124 obtains the period (T1, Tn) of the synchronization signal (V_sync) included in each video signal based on the count value of the counter 122. The period comparison unit 125 compares the period of the synchronization signal between the video signals. Specifically, the period comparison unit 125 includes a period (T1) of a synchronization signal of a reference video signal (for example, a video signal input via the input terminal 1) and a period of a synchronization signal of another video signal ( Tn) is compared to determine whether or not they match. More specifically, the difference (T1−Tn) in the period of the synchronization signal is obtained, and when the difference is equal to or less than a predetermined value, it is determined that the periods match.

  The determination results of the phase comparison unit 127 and the period comparison unit 125 are transmitted to the group determination unit 130.

(Correlation detector)
FIG. 7 is a diagram illustrating a configuration of the correlation detection unit 140 in the MWP 100. The correlation detection unit 140 includes a surrounding pixel information acquisition unit 141 and a pixel value difference calculation unit 143. The surrounding pixel information acquisition unit 141 is provided for each signal line, that is, for each input terminal. The surrounding pixel information acquisition unit 141 acquires information about pixels at the peripheral edge of the video indicated by each video signal. Here, the peripheral portion of the image is a region R1a, R1b, R1c, or R1d of the four sides of the image as shown in FIG.

  The pixel value difference calculation unit 143 inputs the determination result of the group determination unit 130. The pixel value difference calculation unit 143 calculates, as a correlation value between the two images, a square average of the difference between the pixel values of the peripheral portion of the image between the two images indicated by the two image signals in the grouped combination. To do. For example, as shown in FIG. 9, when assuming video 2 and video 3 as video candidates to be arranged adjacent to video 1, as a correlation value between video 1 and video 2, The root mean square of the difference between the pixel value and the pixel value of the peripheral portion R2d of the video 2 is calculated. Similarly, as the correlation value between the video 1 and the video 3, the root mean square of the difference between the pixel value of the peripheral portion R1c of the video 1 and the pixel value of the peripheral portion R3a of the video 3 is calculated. The pixel value difference calculation unit 143 sends the calculated correlation value to the arrangement determination unit 150. In this embodiment, since the correlation value is obtained by the root mean square of the difference, the smaller the value of the correlation value, the higher the correlation between the images.

[1-3. Operation]
The operation of the video display system configured as described above will be described.

  Referring to FIG. 1, each of a plurality of video signal sources sends a video signal to MWP 100 via one or a plurality of signal lines. In the MWP 100, the video signal input unit 110 receives a video signal from each video signal source via an input terminal to which a signal line is connected. The video signal received by the video signal input unit 110 is sent to the synchronization signal detection unit 120. The synchronization signal detection unit 120 extracts the synchronization signal from each video signal, compares the period and phase of the synchronization signal between the video signals, and outputs the comparison result.

  The group determination unit 130 performs video signal group determination (that is, grouping) based on the comparison result of the period and phase of the synchronization signal. That is, it is considered that video signals from the same video signal source have the same period and the same phase with respect to the synchronization signal. Therefore, it is possible to group the video signals for each video signal source by determining that the video signals having the same phase and phase as the synchronization signal are in the same group. That is, even when various video signals are mixedly input as shown in FIG. 10A, the video signals are grouped based on the period and phase of the synchronization signal of the video signal as shown in FIG. By dividing, grouping for each video signal source becomes possible.

  Each video signal input via the video signal input unit 110 is simultaneously sent to the correlation detection unit 140 in addition to the synchronization signal detection unit 120. The correlation detection unit 140 refers to the result of group determination by the group determination unit 120 and detects the correlation of the video between the video signals in the group for each group. The arrangement determination unit 150 determines the arrangement of the video indicated by the video signal input via each input terminal for each group based on the detection result of the correlation detection unit 140. That is, as shown in FIG. 10C, the video arrangement is determined based on the correlation between the videos. Thereby, the video can be reconstructed for each group (that is, for each video signal source).

  The determination result by the group determination unit 120 and the determination result of the video arrangement by the arrangement determination unit 150 are sent to the multi-window processing unit 170 together with each video signal. At this time, an image synthesized based on the group determination result, the image arrangement determination result, and the image signal is displayed on the display screen 220 of the controller 200 (see FIG. 3). While viewing the video on the display screen 220, the user can operate the operation unit 160 to select a video to be displayed on the multi-display 10, change the size of the video, adjust the arrangement, and the like.

  When the user finally determines conditions such as size and arrangement via the operation unit 160, the multi-window processing unit 170 outputs an output video (composite video) from the determined conditions and each input video signal. Is transmitted to the video dividing unit 180. The multi-window processing unit 170 arranges the video according to the arrangement determined by the arrangement determination unit 150 for each group, and thereby reconstructs the video transmitted by being divided from the video signal source. Furthermore, the multi-window processing unit 170 generates an output video (synthesized video) by adjusting and synthesizing the size and position of the video from each video signal source according to a user instruction.

  The video dividing unit 180 divides the composite video according to the number of video display devices constituting the multi-display 10, and generates and outputs a video signal for each video display device.

  The multi display 10 receives a video signal from the MWP 100, and each video display device displays a video based on the received video signal. Thereby, the multi-display 10 can display a plurality of videos from a plurality of video signal sources as one video.

  As described above, the MWP 100 automatically groups a plurality of divided input video signals, and automatically arranges and reconfigures the videos within the group. With this configuration, when video signals are input from a plurality of video signal sources via a plurality of signal lines, and the video of each video signal is combined and displayed as one video, the user can connect the signal lines to the MWP. It is possible to reduce the user's trouble in connecting the signal lines and improve convenience.

(Group judgment processing)
FIG. 11 is a flowchart of group determination processing by the group determination unit 130. Hereinafter, the group determination process will be described with reference to the flowchart of FIG. In the following description, for convenience of explanation, it is assumed that signal lines from a plurality of video signal sources are connected from the input terminal 1 to the input terminal N. In FIG. 11, N is the number of input video signals, G1 to GN are group numbers for the input terminals 1 to N (that is, video signals input to the input terminals 1 to N), and T1 to TN are synchronizations of the video signals. The signal period, P1 to PN, is the phase of the synchronization signal of each video signal.

  First, the group determination unit 130 sets 1 to N in G1 to GN in the initial state (S11). The group determination unit 130 sequentially selects two video signals from a plurality of input video signals (S12, S13, S16, S17), and the period and phase of the synchronization signal (V_sync) between the two selected video signals. Are determined to match (S14). The group determination unit 130 obtains the synchronization signal cycle consistency determination result and the phase consistency determination result from the synchronization signal detection unit 120, respectively, and performs the determination in step S14 with reference to the determination results. When the period and phase of the synchronization signal match between two video signals (that is, when each error is equal to or less than the respective threshold), the larger group number of the two video signal group numbers is the smaller one (S15). As a result, the video signals can be grouped (group determination). By grouping based on the period and phase of the synchronization signal as described above, video signals from the same video signal source can be grouped into the same group.

(Placement determination process)
FIG. 12 is a flowchart showing the arrangement determination process by the arrangement determination unit 150. Hereinafter, the arrangement determination process will be described with reference to the flowchart of FIG. The placement determination process by the placement determination unit 150 is performed for each group determined by the group determination unit 130. In the following, for convenience of explanation, a group composed of four video signals will be described as an example. Further, the correlation value between two adjacent videos calculated by the pixel value difference calculation unit 143 is D, the threshold is d, and the number of sides adjacent between the videos is m.

  When one synthesized video is composed of four videos based on four video signals, 23 types of shapes are conceivable as shapes of the synthesized video, as shown in FIGS. Furthermore, for each of the 23 types of shapes, the arrangement pattern of 4 images is 4! = 24 types exist.

  For each shape (S21, S22, S25, S26), the arrangement determining unit 150 calculates an average (ΣD / m) of correlation values D at the peripheral edge between adjacent videos (S23). For example, for the shape of FIG. 13A, as shown in FIG. For the arrangement pattern 1, the arrangement determination unit 150 receives, from the correlation detection unit 140, a correlation value D1c2a between adjacent edges of video 1 and video 2, and a correlation value D1d3b between adjacent edges of video 1 and video 3. Then, a correlation value D3c4a between adjacent edges of the video 3 and the video 4 and a correlation value D2d4b between adjacent edges of the video 2 and the video 4 are acquired, and an average value (ΣD / m) thereof is obtained.

  The arrangement determination unit 150 compares the average of correlation values D (ΣD / m) with a threshold value (S24), and if the average of correlation values D (ΣD / m) is equal to or less than the threshold value, it is specified by an arrangement pattern that gives the average value. The arrangement to be performed is determined as the arrangement of four videos related to the group (S27).

  As described above, in the video display system according to the present embodiment, a plurality of video signals (see FIG. 10A) are grouped based on the characteristics of the synchronization signal (see FIG. 10B), and thereafter each group. The video arrangement pattern is determined based on the correlation value of the adjacent edges between the videos (see FIG. 10C). Thereby, even when various video signals are input, an appropriate video can be automatically reconstructed.

[1-4. Effect]
As described above, the MWP 100 (an example of a video signal processing device) according to the present embodiment receives a plurality of video signals and displays the video signals for display on the multi-display 10 (a display area including a plurality of display devices). Is a device that generates The MWP 100 includes a video signal input unit 110 (an example of an input unit) that inputs a plurality of video signals, and a group determination unit 130 that groups the plurality of video signals based on information included in the video signals.

  With the above configuration, the MWP 100 automatically groups a plurality of divided video signals. By grouping the video signals in this way, the video signals in the group can then be automatically or manually arranged as signals from the same video signal source. In this embodiment, the arrangement determining unit 150 determines the arrangement of each video signal in the group for each group, and automatically arranges and reconfigures the video in the group. With this configuration, when video signals are input from a plurality of video signal sources via a plurality of signal lines, and the video of each video signal is combined and displayed as one video, the user can connect the signal lines to the MWP. It is possible to reduce the user's trouble in connecting the signal lines and improve convenience.

(Embodiment 2)
In the present embodiment, another example of the placement determination process by the placement determination unit 150 in the MWP 100 will be described. In the first embodiment, the arrangement determining unit 150 sets the shape and arrangement, and performs the arrangement determination according to the set shape and arrangement (see FIGS. 12 and 13). On the other hand, in the present embodiment, without setting the shape and arrangement in advance, other videos are arranged at all positions that can be arranged for a certain video, and arranged based on the position having the minimum correlation value. To decide. Hereinafter, the arrangement determination process according to the present embodiment will be described with reference to FIGS. In the following description, for convenience of explanation, a group composed of four video signals each representing video 1 to video 4 will be described as an example.

<Step 1>
First, one of the four images is selected as a reference image, one of the remaining images is arranged adjacent to the four sides of the reference image, and a correlation value D is obtained for each arrangement. Then, the correlation value D is obtained for each arrangement while sequentially changing the images arranged around the reference image. Among the obtained correlation values D, an arrangement that gives the smallest correlation value D (an arrangement of two images) is selected.

  For example, as shown in FIG. 15A, video 1 is selected as the reference video, and video 2 is first arranged adjacent to the four sides of video 1. Then, a correlation value D is obtained for each of the four arrangements (combinations) of video 1 and video 2. Next, the video arranged around video 1 is switched to video 3, and video 3 is arranged adjacent to the four sides of video 1 as shown in FIG. Then, a correlation value D is obtained for each of the four arrangements (combinations) of video 1 and video 3. Next, as shown in FIG. 15C, video 4 is arranged adjacent to the four sides of video 1. Then, a correlation value D is obtained for each of the four arrangements (combinations) of video 1 and video 4. Among the correlation values D obtained as described above, an arrangement that gives the smallest correlation value D is selected. 15A to 15C, the video 2 is adjacent to the right side of the video 1 shown in FIG. 15A, and the video 4 is adjacent to the right side of the video 1 shown in FIG. 15C. Arrangement is selected.

<Step 2>
Subsequently, two videos are arranged according to the arrangement selected in Step 1, one of the remaining pictures is arranged at each of the six positions around the videos, and a correlation value D is obtained for each arrangement. . Thereafter, the correlation value D is similarly obtained for each arrangement while sequentially changing the images arranged around the two images having the arrangement selected in step 1. Then, an arrangement (an arrangement of three images) that gives the smallest correlation value D is selected from the obtained correlation values D.

  For example, as shown in FIG. 16A, images 3 are arranged at six locations around the arrangement (combination) of images 1 and 2 selected in step 1. Then, for each position, a correlation value D between video 3 and video 1 or video 2 adjacent thereto is obtained. Similarly, as shown in FIG. 16 (B), video 4 is arranged at six locations around the arrangement (combination) of video 1 and video 2 selected in step 1, and correlation values D are obtained for each position of video 4. Ask. As for the other arrangement (combination of video 1 and video 4) selected in step 1, video 2 or video 3 is placed around video 1 and video 4 as shown in FIGS. The correlation value D is obtained for each arrangement. And the arrangement | positioning which gives the smallest correlation value D among the calculated | required correlation values D is selected. In FIGS. 16A to 16D, the arrangement shown in FIG. 16A in which video 2 is arranged on the right side of video 1 and video 3 is arranged on the right side of video 2 is selected.

<Step 3>
Finally, three videos are arranged according to the arrangement selected in step 2, the remaining pictures are arranged at respective positions around the eight places, and a correlation value D is calculated for each arrangement. Then, an arrangement that gives the smallest correlation value D is selected.

  For example, as shown in FIG. 17, video 1, video 2, and video 3 are arranged according to the arrangement selected in step 2, video 4 is arranged around those videos, and correlation value D is set for each arrangement. calculate. And the arrangement | positioning in which the correlation value D becomes the minimum, here the arrangement | positioning in which the image | video 4 is located in the right side of the image | video 3 is selected finally.

  As described above, by arranging other images at multiple positions around a certain image, calculating the correlation value for each position, and sequentially determining the position where the correlation value is the smallest, You may decide.

(Other embodiments)
As described above, Embodiments 1 and 2 have been described as examples of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can also be applied to an embodiment in which changes, replacements, additions, omissions, and the like are appropriately performed. Moreover, it is also possible to combine each component demonstrated in the said Embodiment 1-2 and it can also be set as a new embodiment. Therefore, other embodiments will be exemplified below.

  In the first embodiment, group determination is performed using both the cycle and phase of the synchronization signal, but group determination may be performed using only one of them. Note that determination accuracy can be improved by performing group determination using both the period and phase of the synchronization signal.

  In the first embodiment, group determination unit 130 may perform group determination using the correlation value of the video indicated by the video signal instead of the synchronization signal of the video signal. FIG. 18 is a diagram showing the configuration of the MWP in this case. The MWP 100 illustrated in FIG. 18 does not include the synchronization signal detection unit 120 as illustrated in FIG. The correlation detector 140 calculates a correlation value between the input video signals. The group determination unit 130 acquires a correlation value from the correlation detection unit 140, and groups video signals based on the correlation value. For example, the group determination unit 130 groups video signal groups having a correlation value difference within a predetermined range as the same group. This is because divided videos from the same video signal source are considered to be correlated with each other. The arrangement determination unit 150 determines the arrangement of the video for each group based on the outputs from the group determination unit 130 and the correlation detection unit 140. Similarly, in the second embodiment, group discrimination may be performed using the correlation value of the video indicated by the video signal instead of the synchronization signal of the video signal. By grouping based on the correlation value between video signals in this way, video signals from the same video signal source can be grouped into the same group.

  Further, in the first embodiment, after the group determination unit 130 performs group determination based on the synchronization signal of the video signal, in each group determined by the group determination unit 130 in the correlation detection unit 140, the video signal interval is further increased. Grouping may be performed based on the correlation value. For example, the correlation detection unit 140 may further group the video signals by grouping the video signal groups having the correlation value difference within a predetermined range in the group grouped based on the synchronization signal.

  In the correlation detection of the first and second embodiments, the case where there is a frame at the peripheral edge of the video is not considered. In the case of an image having a plain area such as a frame at the periphery of the image, if the correlation value D is calculated by the above-described method, the calculated correlation value D becomes a small value regardless of the actual correlation between the images. . This becomes a cause of erroneous determination in the arrangement determination. Therefore, the pixel value difference calculation unit 143 may determine whether or not the region (edge portion of the image) for which the correlation value D is calculated is a plain region such as a frame. For example, the standard deviation σ of the difference value may be calculated in the region (the edge of the video) where the correlation value D is calculated. When there is a pattern at the edge, σ increases, but when solid frames are adjacent to each other, σ decreases. Therefore, in step S24 in the flowchart of FIG. 12, when the average of the correlation values is equal to or smaller than the threshold value and the standard deviation σ is equal to or larger than the threshold value of the standard deviation, the process may proceed to step S27.

  In addition, the correlation value between images was obtained by calculating the root mean square of the difference between the pixel values of the peripheral part between the images, but if a value indicating the correlation between the images can be obtained, it is calculated by another method. May be.

  In the arrangement determination according to the first embodiment, all the shapes shown in FIG. 13 are set as the determination targets (step S21 in FIG. 12), but only a part of the shapes shown in FIG. For example, only the shape shown in FIG. 13A may be the determination target, or the shapes shown in FIGS. 13A, 13B, and 13F may be the determination target.

  In the first embodiment, in the arrangement determination (step S24 in the flowchart of FIG. 12), the loop is escaped when the average correlation value (ΣD / m) is equal to or less than a predetermined value. The method is not limited to this. For a certain shape, an average value (ΣD / m) of correlation values may be calculated for all arrangements, and it may be determined whether or not the minimum value among the calculated values is equal to or less than a predetermined value d. When the average value (ΣD / m) of the correlation value is larger than the predetermined value d, the process proceeds to the next shape. When the average value is smaller than the predetermined value d, the shape and arrangement at that time are selected. Alternatively, a shape and an arrangement that calculate an average value (ΣD / m) of correlation values for all shapes and all arrangements and give an average value of minimum correlation values may be adopted.

  As described above, the embodiments have been described as examples of the technology in the present disclosure. For this purpose, the accompanying drawings and detailed description are provided.

  Accordingly, among the components described in the accompanying drawings and the detailed description, not only the components essential for solving the problem, but also the components not essential for solving the problem in order to illustrate the above technique. May also be included. Therefore, it should not be immediately recognized that these non-essential components are essential as those non-essential components are described in the accompanying drawings and detailed description.

  Moreover, since the above-mentioned embodiment is for demonstrating the technique in this indication, a various change, replacement, addition, abbreviation, etc. can be performed in a claim or its equivalent range.

  The present disclosure can be applied to a video signal processing apparatus that receives a plurality of video signals indicating divided videos from a plurality of video signal sources and appropriately arranges the plurality of divided videos.

10 Multi-display 100 Multi-window processing device (MWP)
110 video signal input unit 120 synchronization signal detection unit 130 group determination unit 140 correlation detection unit 150 arrangement determination unit 160 operation unit 170 multi-window processing unit 180 video division unit 200 controller

Claims (9)

A video signal processing device that receives a plurality of video signals and generates a video signal for display on a display area configured by a plurality of video display devices,
An input unit for inputting the plurality of video signals;
A group determination unit that groups the plurality of video signals based on information included in the video signal;
Video signal processing device. The group determination unit groups video signal groups in which a difference in period and / or a phase difference of synchronization signals included in the video signal are within a predetermined range as the same group,
The video signal processing apparatus according to claim 1. A correlation detector that calculates a correlation value indicating a correlation between the two video signals;
The group determination unit further groups the video signals in the group determined by the group determination unit based on the correlation value.
The video signal processing apparatus according to claim 2. A correlation detector that calculates a correlation value indicating a correlation between the two video signals;
The group determination unit groups the plurality of video signals based on the correlation value.
The video signal processing apparatus according to claim 1.   The video signal processing apparatus according to claim 1, further comprising an arrangement determination unit that determines an arrangement of each video signal in the group for each group. A correlation detector that calculates a correlation value indicating a correlation between the two video signals;
The video signal processing apparatus according to claim 5, wherein the arrangement determination unit determines the arrangement of the video indicated by the video signal based on a correlation between the video signals in the group for each group.   7. The correlation detection unit according to claim 3, wherein the correlation detection unit calculates the correlation value based on a difference between an edge pixel of an image indicated by one video signal and an edge pixel of an image indicated by another video signal. The video signal processing apparatus according to any one of the above.   The video signal according to claim 1, further comprising: a video processing unit that generates a composite video in which the plurality of video signals are arranged based on the group determined by the group determination unit and the arrangement determined by the arrangement determination unit. Processing equipment.   The video signal processing according to claim 8, further comprising a video dividing unit that divides an output video from the video processing unit according to the number of the video display devices and generates a video signal for each of the video display devices. apparatus.

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