JP2012212061A - Multi-display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a multi-display device in which each of graphic display devices can display images to be displayed without individually performing identification setting in the individual graphic display devices.SOLUTION: A first graphic display device 2a' subjected to cascade connection identifies a predetermined temporal difference of blank periods of a plurality of inputted still image signals to perform video display of corresponding still image signals on a display unit, eliminates vertical synchronous signals of the still image signals to output them to a next graphic display device 2b', and delays a start position of the vertical synchronous signal of each of the plurality of still image signals by the predetermined temporal difference to output it to a next graphic display device 2c'. A next graphic display device 2d' and graphic display devices following it perform signal processing as in the case of the first graphic display device 2a', and do not perform video display of the still image signals on the display unit with the vertical synchronous signals eliminated among a plurality of inputted still image signals and control the vertical synchronous signals of the still image signals.

Description

  The present invention relates to a still image display multi-display device (hereinafter referred to as a multi-display device) that functions as a single display by connecting a plurality of video display devices to each other or through an external device.

  Currently, multi-display devices that connect a plurality of video display devices and function as a single display are widely used. It is characterized by its ability to freely increase or decrease the number of connections according to the environment, usage, and purpose of the installation site, mainly for commercial use such as exhibitions and concerts that require a large screen.

  Since the multi-display device is composed of a plurality of video display devices, it is necessary to transmit a video signal to each video device. Several conventional video signal transmission methods will be described with reference to FIGS.

  FIG. 10 is a configuration diagram of the multi-display display system disclosed in Patent Document 1. It is composed of a video signal generator 1 that generates a still image signal and nine video display devices 2a to 2i.

  The video signal generator 1 divides the video into nine parts and generates a 2i still picture signal from each video display device 2a in order to support nine video display devices connected in cascade by means such as daisy chain connection. Each still image signal is output to the video display device 2a.

  FIG. 11 is a diagram illustrating a timing chart of a still image signal output from the video signal generator 1 of Patent Document 1 and a video image when the video is temporarily displayed. (A) to (i) of FIG. 11 are timing charts of still image signals divided into 9 parts for the video display devices 2a to 2i, and the right side of these still image signals is temporarily put on a normal video display device. A video image when displayed is shown. In (a) to (i) of FIG. 11, the display start position of the original video signal is generally delayed by a time difference based on the television signal standard from the start position that is the rising position of the vertical synchronization signal. Although the original video signal is not shown, all the video signals of one still image are displayed as usual in the display area of a normal video display device. Further, in FIGS. 11A to 11I, the start positions of the video signals for the respective video display devices 2a to 2i are sequentially shifted by a predetermined time difference “A” with respect to the display start position of the original video signal. The video blank periods “A” to “9A” are formed in each still image signal with a delay. Accordingly, as shown in FIGS. 11A to 11I, when the video blank period “A” to “9A” is widened, when the image is temporarily displayed on a normal video display device, (i) to (i) in FIG. As shown on the right side of (), the video image is generated by a black belt-like area extending above the display area of a normal video display device, and the display is shifted downward as a whole (a part of the video is displayed in the display area). The video that protrudes below.

  For example, FIG. 11A is a timing chart of a still image signal for the video display device 2a. The timing chart shows that the difference between the original video signal display start position and the video signal display start position of the video display device 2a is “A”. In the video image, it can be confirmed that a black belt-like region is generated above the display region as a video blank period by “A”. Similarly, it can be confirmed that FIGS. 11B to 11I have different video blank periods of “2A” to “9A”, respectively. These still image signals shown in FIGS. 11A to 11I are sequentially output from the video signal generator 1 shown in FIG. 10 serially.

  The operation of the video display device 2a will be described with reference to FIGS.

  FIG. 12 is a block diagram of a video display device 2a according to Patent Document 1. The interior includes a display unit 40, a remote control light receiving unit 60, a display position detection unit 33, an image processor 36, a CPU 37, and the like. When the still image signals shown in FIGS. 11A to 11I output from the video signal generator 1 are input to the video display device 2a, the video display device 2a performs the following processing. First, the display position detection unit 33 detects each video blank period of the video signal for each video display device, and the CPU 37 compares it with a set value of a video blank period set and stored in advance by the user, which will be described later. As a result of comparison, if the value “A” of the detected video blank period of the still image signal matches the value “A” of the video blank period previously stored in the video display device 2a, the still image signal is converted into an image processor. The video is processed at 36 and displayed on the display unit 40. If they do not match, video display is not performed.

  Next, the setting value of the video blank period set and stored in advance by the user will be described.

  FIG. 13 is a video signal identification setting screen of the video display devices 2a to 2i of Patent Document 1. In order to identify the still image signal transmitted from the video display devices 2a to 2i, the video signal identification number “1” corresponding to each video blank period “A”... “9A” is assigned to each video display device. ... "9" is set. For example, in the video display device 2a, as shown in FIG. 13A, “1” is set by the user's remote control operation, and the video blank period “A” is stored in the video display device 2a. In the video display device 2b, as shown in FIG. 13B, “2” is set by the user's remote control operation, and the video blank period “2A” is stored in the video display device 2b. This remote control operation by the user is sequentially repeated for the number of video display devices. Finally, “9” is set in the video display device 2i, and the video blank period “9A” is stored in the video display device 2i.

  When a still image signal for the video display device 2a is input to the video display device 2a, the video blank period “A” is detected and compared with the video blank period “A” previously set and stored in the video display device 2a. To do. If it is determined that they are the same, the start position of the video signal for (a) video display device 2a in FIG. 11 is returned to the original video signal start position, and the video is displayed on the display unit 40 of the video display device 2a. Display. In addition, when the value of the video blank period detected from each still image signal and the value of the video blank period stored in each video display device are not the same, the video is not displayed.

  Similarly, the video display devices 2b to 2i display only the still image signals corresponding to the video blank periods “2A” to “9A” corresponding thereto.

Japanese Patent Application 2010-220724 (filed on September 30, 2010)

  However, the multi-display device of Patent Document 1 is characterized in that the video display devices 2a to 2i identify a video blank period in which there is a difference between still image signals for the video display device 2a to 2i. For this reason, it is necessary for the user to make individual settings for each video display device in advance so as to operate in different video blank periods. As the number of video display devices 2a to 2i in FIG. There was a problem.

  Therefore, the present invention has been made in view of the above-described problems, and an object of the present invention is to individually use each video display device in a multi-display device that uses a still image signal having a difference in a video blank period. A multi-display device is realized in which each video display device can determine a still image signal to be displayed and display a video without performing identification setting.

  In order to achieve the above object, a multi-display apparatus according to the present invention is a multi-display apparatus in which a plurality of video display apparatuses each displaying a still image signal obtained by dividing one video into a plurality of images are connected in cascade. The still image signal is composed of at least a video signal and a vertical synchronizing signal, and the actual display start position of each of the plurality of video signals is sequentially delayed by a predetermined time difference from the display start position of the original video signal. An image blank period is formed in the still image signal, and the plurality of image display devices include a display unit that displays the image of the still image signal and a synchronization control unit that controls the vertical synchronization signal. The video display device identifies the predetermined time difference between the video blank periods of the plurality of input still image signals and displays the corresponding still image signals as the table. The video is displayed on the display unit, and the vertical synchronization signal of the corresponding still image signal is deleted by the synchronization control unit and output to the next video display device, and the vertical synchronization of each of the still image signals is displayed. The start position of the signal is delayed by the predetermined time difference and output to the next video display device, and the next video display device and the subsequent video display device perform signal processing in the same manner as the first video display device. In addition, for the still image signal from which the vertical synchronization signal has been deleted from among the plurality of input still image signals, the synchronization control unit does not display the still image signal on the display unit. The vertical synchronization signal of the still picture signal is not controlled.

  Also, the multi-display device of the present invention is a multi-display device in which a plurality of video display devices that respectively display still images signals obtained by dividing one image into a plurality of images are connected in cascade, and the still image signals are at least The video signal is composed of a video signal and a vertical synchronization signal, and the original display start position of the video signal is delayed from the start position of the vertical synchronization signal by a time difference based on a television signal standard. The actual display start position of the signal is sequentially delayed by a predetermined time difference with respect to the display start position of the original video signal to form a video blank period in the still image signal. A display unit for displaying a still image signal as a video image and a synchronization control unit for controlling the vertical synchronization signal. The first still image signal is displayed on the display unit by identifying the predetermined time difference between the video blank periods of the plurality of still image signals, and the synchronization control unit displays the first still image signal vertically. The synchronization signal is deleted and output to the next video display device, and the start position of the vertical synchronization signal of each still image signal following the first still image signal is delayed by the predetermined time difference to the next video The next video display device that is output to the display device and the video display device that follows the video display device are configured to output the still image signal from which the vertical synchronization signal has been deleted from among the plurality of input still image signals. The still image signal is not displayed on the display unit, the vertical control signal of the still image signal is not controlled by the synchronization control unit, and the still image signal from which the vertical synchronization signal has not been deleted. As in the first video display device, the predetermined time difference between the video blank periods of the plurality of input still image signals is identified and the corresponding still image signal is displayed on the display unit. The vertical synchronization signal of the corresponding still image signal is deleted and output to the next video display device by the synchronization control unit, and the vertical synchronization of each still image signal following the corresponding still image signal is output. The start position of the signal is delayed by the predetermined time difference and output to the next video display device.

  The multi-display apparatus according to the present invention is characterized in that a divided arrangement of the still image signal obtained by dividing one video into a plurality of positions corresponds to an arrangement of a plurality of video display apparatuses.

  The multi-display device of the present invention is characterized in that the order of the plurality of video signals of the still image signal obtained by dividing one video into a plurality of times corresponds to the order of the plurality of video display devices connected in cascade. To do.

  In the multi-display device of the present invention, the video blank period of each of the plurality of still image signals input to the first video display device connected in cascade is a period obtained by sequentially multiplying the predetermined time difference by an integer. It is characterized by.

  The multi-display device of the present invention is a multi-display device that uses a still image signal having a difference in the video blank period, and each video display device does not have to be individually identified and set in each video display device. A multi-display device capable of discriminating a still image signal to be displayed and displaying a video is realized.

1 is a configuration diagram of a multi-display display system according to an embodiment. It is a block diagram of the video signal generator concerning this example. 1 is a block diagram of a video display device according to the present invention. It is an image figure of the image | video by which the division | segmentation process is carried out with the video signal generator which concerns on this invention. FIG. 2 is a timing chart of each still image signal at point a in FIG. 1 and a video image when the still image signal is temporarily displayed as a video. FIG. 2 is a timing chart of a still image signal at a point b in FIG. 1 and a video image when the still image signal is temporarily displayed as a video. FIG. 2 is a timing chart of a still image signal at a point c in FIG. 1 and a video image when the still image signal is temporarily displayed as a video. FIG. 2 is a timing chart of a still image signal at point i in FIG. 1 and a video image when the still image signal is temporarily displayed as a video. It is the figure which showed the display state of the video display apparatus which concerns on this invention in time series. 1 is a configuration diagram of a multi-display display system of Patent Document 1. FIG. FIG. 10 is a diagram illustrating still image signals and video images transmitted from the video signal generator of Patent Document 1. It is a block diagram of the video display apparatus concerning patent documents 1. 7 is a video signal identification setting screen of the video display device of Patent Document 1.

  Embodiments of the present invention will be described below. The same reference numerals are used to describe the same configuration of the present invention as the configuration of the prior art of Patent Document 1 described with reference to FIGS. First, the configuration of the device in the present embodiment will be described with reference to FIGS. 1 to 3.

  FIG. 1 is a configuration diagram of a multi-display display system according to the present embodiment. Reference numeral 1 denotes a video signal generator for generating a still image signal. Reference numerals 2a 'to 2i' denote video display devices, which constitute a nine-screen multi-display device as a whole. The still image signal output from the video signal generating device 1 is input to the video display device 2a ′, and thereafter is sequentially output to the video display device 2i ′ by cascade connection such as daisy chain connection. In addition, since the resolution of each video display apparatus in the present embodiment is set to horizontal 1920 × vertical 1080, the resolution is horizontal 5760 × vertical 3240 on nine sides.

  FIG. 2 is a block diagram of the video signal generator 1 according to the present embodiment, which is the same as the configuration of the video signal generator 1 of Patent Document 1 of the prior art. The video signal generator 1 includes a PC (personal computer) 20 and a video signal transmission unit 10, and the video signal transmission unit 10 includes an image memory 11, a graphics controller 12, a video signal control unit 13, and an HDMI output unit 14. It is configured. The PC 20 can generate and output video data. Video data output from the PC 20 is input to the graphics controller 12. The graphics controller 12 divides the video data into nine parts, uses the image memory 11 to adapt to the video format, and generates a still picture signal that is time-divided by one-ninth of each picture.

  The still picture signal described in detail in FIG. 5 includes a vertical synchronizing signal, a horizontal synchronizing signal, and a dot clock. The still image signal generated by the graphics controller 12 is input to the video signal control unit 13. The video signal control unit 13 performs a process of forming a video blank period for each still image signal according to a control signal from the graphics controller 12.

  In a general still image signal, the display start position of the original video signal is generally delayed by a time difference based on the television signal standard from the start position that is the rising position of the vertical synchronization signal. The still image signal of the embodiment of the present invention is the same as the still image signal output from the video signal generator 1 of FIG. 10 which is the prior art. As shown in FIG. Video blank periods “A” to “9A” are formed in each still image signal by sequentially delaying by the time difference “A”. The video signal output from the video signal control unit 13 is output to the video display device 2a ′ via the HDMI output unit 14.

  Next, the video display device constituting the multi-display device will be described.

  FIG. 3 is a block diagram of a video display apparatus according to the present invention. Reference numeral 2a ′ surrounding the entire block diagram represents a video display device, which includes a scaler 30, a display unit 40, and an image memory 50. The scaler 30 includes an HDMI output unit 31, an HDMI input unit 32, a display position detection unit 33, a ROM 34, The RAM 35, the image processor 36, the CPU 37, the flash memory 38, and the synchronization control unit 39 are configured. The video display devices 2b 'to 2i' in FIG. 1 have the same configuration as the video display device 2a 'in FIG. Further, the difference between the image display devices 2a 'to 2i' of the embodiment of the present invention and the image display devices 2a to 2i of Fig. 12 which is the prior art is that the former has the synchronization control unit 39 and the latter. 12 is that the remote control light receiving unit 60 is not provided.

  The CPU 37 controls the entire scaler 30, and a display position detection unit 33, a ROM 34, a RAM 35, an image processor 36, and a synchronization control unit 39 are connected to the CPU 37.

  The ROM 34 stores a program for operating the video display device 2a ′, and the CPU 37 expands the contents of the ROM 34 to the RAM 35 and executes the program. Further, the ROM 34 stores a value “A” of a video blank period to be identified for the purpose of identifying a still image signal to be displayed on the video display device 2a. This value is common to all connected video display devices 2a 'to 2i'.

An HDMI standard format signal input from the video signal generator 1 is input to the HDMI input unit 32, and a video signal, a horizontal synchronization signal, a vertical synchronization signal, and a signal obtained by decoding a dot clock are extracted. The HDMI input unit 32 is connected to the HDMI output unit 31, the display position detection unit 33, and the image processor 36, and outputs each signal extracted from each HDMI input unit 32 to these units.
The synchronization control unit 39 can delete or delay the vertical synchronization signal received from the HDMI input unit 32 according to an instruction from the CPU 37 and output it to the HDMI output unit 31.
Therefore, only the vertical synchronization signal input from the HDMI input unit 32 is connected to the HDMI output unit 31 via the synchronization control unit 39.

  The display position detector 33 detects a predetermined time difference in the video blank period of the input still image signal. The method for detecting the video blank period is to determine the position corresponding to the display position of the original video signal with reference to the rising start position of the vertical synchronization signal shown in FIG. 5A, and display each video image actually input from that position. It can be measured from the time difference to the start position of the video signal for the device.

  As another method different from the present embodiment, it is also possible to sample the period until the start of the video signal with the dot clock based on the horizontal synchronization signal.

  The CPU 37 compares the video blank period of the still image signal detected by the display position detection unit 33 with the video blank period “A” common to the video display devices 2a ′ to 2i ′ stored in the ROM 34, and the input still image signal is It is determined whether it should be displayed on the video display device 2a '. When the video blank period of the input still image signal is a predetermined time difference “A”, it is determined that the still image signal is to be displayed, and the CPU 37 instructs the image processor 36 to execute the processing of the video signal, and the image The video signal is developed in the memory 50, and is returned to a normal video without a predetermined time difference “A” of the video blank period such as the video image on the right in FIG. At the same time, the CPU 37 instructs the synchronization control unit 39 to delete the vertical synchronization signal for the video display device 2 a ′ and output it to the HDMI output unit 31. If the video blank period of the input still image signal detected by the display position detector 33 is determined to be other than “A”, that is, a still image signal that should not be displayed by the video display device 2a ′, the CPU 37 Without instructing the process of displaying the video signal of the still image on the display unit 40, the synchronization control unit 39 delays the vertical synchronization signal by a predetermined time difference “A” period (details will be described later) and outputs it to the HDMI output unit 31. The video display device 2a ′ continues to display the video of the displayed still image signal until a new still image signal to be displayed is input.

  In the present embodiment, the means for causing the synchronization control unit 39 to retract the vertical synchronization signal for the “A” period for the still image signal that should not be displayed has been described. The video signal may be advanced in the “A” period. The above is the description of the device configuration of the video display device 2a ′, and the video display devices 2b ′ to 2i ′ have the same configuration.

  Next, generation of a video signal in the video signal generator 1 of the present embodiment will be described with reference to FIGS. 4 and 5.

  FIG. 4 is an image diagram of a video processed by the video signal generator 1 according to the present invention. 4A shows “ellipse” video data having a resolution of 5760 × 3240 generated by the PC 20 of FIG. FIG. 4B shows that the video of FIG. 4A is divided into nine parts by the graphics controller 12, and each represents video data with a resolution of 1920 × 1080. The video data divided into nine parts by the graphic controller 12 is converted into video signals by 1/9 and input to the video signal control unit 13 as a still picture signal together with a horizontal synchronizing signal and a vertical synchronizing signal. The signals divided into nine and input to the video signal control unit 13 are the original video signals described above with reference to FIG.

  FIG. 5 shows a timing chart of each still image signal at point a in FIG. 1, and the right side shows a video image when these still image signals are temporarily displayed on a normal video display device. FIG. 5A to FIG. 5I show still image signals divided into nine for the video display devices 2a ′ to 2i ′. The timing chart is an arrangement of a vertical synchronization signal, an original video signal, a video signal for each video display device, and a horizontal synchronization signal. Note that the original video signal in the timing chart of each still image signal is described for comparison, and does not actually exist from point a to point i in FIG. In addition, a video image when the video is temporarily displayed according to the video signal of FIGS. 5A to 5I is shown on the right side of the timing chart.

  2 receives the instruction from the graphics controller 12, and delays the display start position of the video signal in FIGS. 5A to 5I by a predetermined time difference “A”. This difference appears as a video blank period in the video image. For example, in FIG. 5A, there is a predetermined time difference “A” between the display start position of the original video signal and the display start position of the video signal for the video display device 2a ′, and “A” in the video image. The video blank period is generated by the amount of. Similarly, in FIG. 5B to FIG. 5I, video blank periods different from “2A”, “3A”... “9A” are provided. As shown in FIG. 5, video blank periods “A”, “2A”, “3A”... “9A” of a plurality of still picture signals input to the first video display device 2a ′ connected in cascade are The predetermined time difference “A” is a period obtained by sequentially multiplying by an integer.

  The video signals for the video display devices shown in FIGS. 5A to 5I are time-divisioned in the order of FIGS. 5A to 5I together with the vertical synchronizing signal and the horizontal synchronizing signal. The signal is input from the signal control unit 13 to the HDMI output unit 14. As a supplement, the detection of the predetermined time difference in the video blank period is performed by using the original video signal with reference to the rising start position of the vertical synchronization signal shown in FIG. The position corresponding to the display position can be determined and measured from the time difference from that position to the start position of the video signal for each video display device actually input.

  In the HDMI output unit 14 of FIG. 2, it is converted into an HDMI standard format still image signal and output to the video display device 2a ′.

  Processing of still image signals in the multi-display apparatus of the present embodiment will be described with reference to FIGS.

  FIG. 6 is a timing chart of still image signals at the point b in FIG. 1, and the right side thereof represents a video image when these still image signals are temporarily displayed on a normal video display device. FIGS. 6 (a ′) to 6 (i ′) show still image signals and video images after the synchronization signal processing is performed by the video display device 2a ′.

  The timing charts shown in FIGS. 6 (a ′) to 6 (i ′) are, in order from the top, the vertical synchronization signal, the original video signal, the video signal for each video display device, and the horizontal synchronization signal. The original video signal is described for comparison. In addition, a video image when temporarily displayed on a normal video display device according to each still image signal of FIGS. 6A 'to 6I' is shown on the right side of the timing chart.

  The video display device 2a ′ receives each still image signal shown in FIGS. 5A to 5I at the point a in FIG. 1, performs the video blank period detection and video display processing, and also performs the synchronization control unit 39. Thus, the point b is converted into the still image signals shown in FIG. 6 (a ′) and FIG. 6 (i ′).

  Specifically, in the still image signal for the video display device 2a ′ shown in FIG. 6 (a ′), a vertical synchronizing signal exists as shown in FIG. 5 (a) at the point a in FIG. However, at the point b in FIG. 1, the vertical synchronization signal is deleted by the synchronization control unit 39 of the video display device 2a ′ as shown in FIG. 6 (a ′). Accordingly, even if the video display devices 2b 'and 2i' after the video display device 2a 'receive the still image signal for the video display device 2a', the vertical synchronization signal is deleted, so that the video display is not performed. Become.

  Also, the video blank period of the video signal for the video display device 2b ′ shown in FIG. 6 (b ′) is “2A” as shown in FIG. 5 (b) at the point a in FIG. The point b of 1 is converted to “A” as shown in FIG. Thus, when the video display device 2b ′ receives the still image signal, the video blank period is “A”, and video display is executed.

  Further, the video blank period of the video signal for the video display device 2c ′ shown in FIG. 6C ′ is changed from “3A” at the point a in FIG. 1 to “2A” at the point b in FIG. Thereafter, the same conversion is performed, and the video blank period of the video signal for the video display device 2i ′ shown in (i ′) is “9A” at point a in FIG. Converted to “8A” at the point.

  FIG. 7 shows a timing chart of still image signals at point c in FIG. 1, and the right side thereof shows a video image when these still image signals are temporarily displayed on a normal video display device. FIG. 7 (a ″) to FIG. 7 (i ″) show still image signals and video images after being processed by the video display device 2b ′.

  The timing charts shown in FIG. 7 (a ″) to FIG. 7 (i ″) are a vertical synchronization signal, an original video signal, a video signal for each video display device, and a horizontal synchronization signal in order from the top. The original video signal is described for comparison. In addition, a video image when it is temporarily displayed on a normal video display device in accordance with the still image signal of FIG. 7 (a ″) to FIG. 7 (i ″) is shown on the right side of the timing chart.

  The video display device 2b ′ receives the still image signal shown in FIG. 6 (a ′) to FIG. 6 (i ′) at the point b in FIG. 1, performs the video blank period detection and the video display processing, and simultaneously performs synchronization. The control unit 39 converts the signal waveform shown in FIG. 7 at point c in FIG. 7 (a ″) to the signal waveform shown in FIG. 7 (i ″).

  Specifically, in the still image signal for the video display device 2a ′ shown in FIG. 7 (a ″), since there is no vertical synchronization signal at the point b, the display position detection unit 33 in FIG. 3 detects the vertical synchronization signal. do not do. If the vertical synchronizing signal is not detected, the image processing in the image processor 36 in FIG. 3 is not performed and the image is not displayed on the display unit 40.

  Further, since the video blank period of the video signal for the video display device 2b ′ shown in FIG. 7 (b ″) is converted to “A” at the point b in FIG. 1, the video display device 2b ′ displays the video. While performing the processing, the vertical synchronization signal is deleted by the synchronization control unit 39 of the video display device 2b ′ at the point c in FIG. Thus, even if the video display devices 2c ′ to 2i ′ receive the still image signal for the video display device 2b ′, the video display is not performed.

  Further, the video blank period of the video signal for the video display device 2c ′ shown in FIG. 7 (c ″) is changed from “2A” at the point b in FIG. 1 to “A” at the point c in FIG. It has been converted. Thus, when the video display device 2c ′ receives the still image signal, the video blank period is “A”, and video display is executed. The same conversion is performed thereafter, and the video blank period of the video display device 2i shown in FIG. 7 (i ″) is “8A” at the point b in FIG. 1, but is “7A” at the point b in FIG. Is converted to.

  FIG. 8 shows a timing chart of still image signals at point i in FIG. 1, and the right side shows a video image when these still image signals are temporarily displayed on a normal video display device. FIG. 8 (a ′ ″) to FIG. 8 (i ″ ′) show still image signals and video images after being processed by the video display device 2c ′.

  The timing charts shown in FIG. 8 (a ′ ″) to FIG. 8 (i ′ ″) are, in order from the top, the vertical synchronization signal, the original video signal, the video signal for each video display device, and the horizontal synchronization signal. is there. The original video signal is described for comparison. Further, a video image when it is temporarily displayed on a normal video display device in accordance with the still image signal of FIG. 8 (a ′ ″) to FIG. 8 (i ″ ′) is shown on the right side of the timing chart.

  The video display device 2i ′ receives the still image signal shown in FIG. 8 (a ′ ″) to FIG. 8 (i ′ ″) at the point i in FIG. 1, and performs video blank period detection and video display processing. To do.

  Specifically, the still image signal for the video display device 2a ′ shown in FIG. 8 (a ′ ″) does not perform any processing because there is no vertical synchronization signal.

  Also, the still image signal for the video display device 2b ′ shown in FIG. 8 (b ′ ″) is not subjected to any processing because there is no vertical synchronizing signal.

  Similarly, the still image signal for the video display device 2c ′ shown in FIG. 8 (c ′ ″) is not processed because there is no vertical synchronizing signal.

  The video blank period of the still image signal for the video display device 2i ′ shown in FIG. 8 (i ′ ″) is converted to “A” at the point i in FIG. Perform video display processing. The above is the explanation of the processing of the still image signal in the multi-display apparatus of the present embodiment.

  Next, the display state of the video display device according to the present invention will be described.

  FIG. 9 is a diagram showing the display state of the video display device according to the present invention in time series. FIG. 9 (0) is an initial state, and nothing is displayed. FIG. 9A shows a state in which the still image signal (FIG. 5A), which is the first time-divided signal, is displayed on the video display device 2a, that is, the upper left screen. Thereafter, FIG. 9I shows a state in which still image signals are sequentially input, nine screens are input, and all the displays are completed. As described above, the divided arrangement of the still image signal obtained by dividing one video shown in FIG. 4B corresponds to the arrangement of the video display devices 2a ′ to 2i ′ shown in FIGS. 9A to 9I. ing. Then, the order of the plurality of video signals of the still image signal obtained by dividing one video shown in FIG. 4B and the order of the video display devices 2a ′ to 2i ′ shown in FIGS. It corresponds.

  The above is the description of the video signal generator 1 and the video display devices 2a ′ to 2i ′ in the present embodiment. By implementing the present embodiment, the still image signal does not use a separate identification signal other than the vertical synchronization signal, the video signal, and the horizontal synchronization signal, and the video blank period of each video display device as in Patent Document 1 is used. There is no need for individual setting, and video display by a multi-display device can be realized.

  Note that the still image display operation displayed on the plurality of video display devices described in the above embodiments is regarded as “one frame of a moving image”, and a still image signal is transferred and displayed at high speed (for example, 30 frames per second). Thus, the present invention can also handle moving images.

  The present invention can be widely applied to a multi-display device that connects a plurality of video display devices and functions as an integrated display unit.

1 Video signal generator 2a, 2b, 2c, 2d, 2e, 2f, 2g, 2h, 2i, 2a ', 2b', 2c ', 2d', 2e ', 2f', 2g ', 2h', 2i ' Display device 11 Image memory 12 Graphics controller 13 Video signal control unit 14 HDMI output unit 20 PC
30 Scaler 31 HDMI output unit 32 HDMI input unit 33 Display position detection unit 34 ROM
35 RAM
36 Image processor 37 CPU
38 Flash memory 39 Synchronization control unit 40 Display unit 50 Image memory

Claims (5)

A multi-display device in which a plurality of video display devices for displaying still image signals obtained by dividing one video into a plurality of images are connected in cascade,
The still image signal is composed of at least a video signal and a vertical synchronization signal,
A video blank period is formed in the still image signal by sequentially delaying an actual display start position of each of the plurality of video signals by a predetermined time difference from a display start position of the original video signal,
The plurality of video display devices have a display unit that displays the still image signal as a video and a synchronization control unit that controls the vertical synchronization signal,
The first video display device in cascade connection identifies the predetermined time difference between the video blank periods of the plurality of input still image signals and displays the corresponding still image signals on the display unit, The synchronization control unit deletes the vertical synchronization signal of the corresponding still image signal and outputs it to the next video display device, and sets the start position of the vertical synchronization signal of each of the plurality of still image signals to the predetermined Delay the time difference and output to the next video display device,
The next video display device and the subsequent video display device perform signal processing in the same manner as the first video display device, and the vertical synchronization signal is deleted from the plurality of input still image signals. As for the still image signal, the still image signal is not displayed on the display unit, and a vertical synchronization signal of the still image signal is not controlled by the synchronization control unit. A multi-display device in which a plurality of video display devices for displaying still image signals obtained by dividing one video into a plurality of images are connected in cascade,
The still image signal is composed of at least a video signal and a vertical synchronization signal,
The original display start position of the video signal is delayed by a time difference based on the television signal standard from the start position of the vertical synchronization signal, but the actual display start position of each of the plurality of video signals is the original display position. A video blank period is formed in the still image signal by sequentially delaying the display start position of the video signal by a predetermined time difference,
The plurality of video display devices have a display unit that displays the still image signal as a video and a synchronization control unit that controls the vertical synchronization signal,
The first video display device in cascade connection identifies the predetermined time difference between the video blank periods of the plurality of input still image signals and displays the corresponding still image signals on the display unit, The synchronization control unit deletes the vertical synchronization signal of the corresponding still image signal and outputs it to the next video display device, and sets the start position of the vertical synchronization signal of each of the plurality of still image signals to the predetermined Delay the time difference and output to the next video display device,
The next video display device and the subsequent video display device are:
Of the plurality of input still image signals, the still image signal from which the vertical synchronization signal has been deleted is not displayed on the display unit, and the synchronization control unit does not display the still image signal. Without controlling the vertical sync signal of the image signal
For the still image signal from which the vertical synchronization signal has not been deleted, as in the first video display device, the predetermined time difference between the video blank periods of the plurality of input still image signals is identified and applied. The still image signal to be displayed is displayed on the display unit, the vertical synchronization signal of the corresponding still image signal is deleted and output to the next video display device by the synchronization control unit, and the corresponding still image is output. A multi-display device, wherein a start position of the vertical synchronization signal of each still image signal following a signal is delayed by the predetermined time difference and output to the next video display device.   The multi-display device according to claim 1, wherein a division arrangement of the still image signals obtained by dividing one video into a plurality of video images and a plurality of video display devices correspond to each other.   4. The multi-display according to claim 3, wherein the order of the plurality of video signals of the still picture signal obtained by dividing one video into a plurality of times corresponds to the order of the plurality of video display devices connected in cascade. apparatus.   5. The video blank period of each of the plurality of still image signals input to the first video display device connected in cascade is a period obtained by sequentially multiplying the predetermined time difference by an integer. Multi-display device.