JP2620651B2 - Multi-screen display device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an enlargement for executing image expansion data and supplying an image signal for enlarged display to a multi-monitor device formed by arranging a plurality of image monitors in a matrix. The present invention relates to a large-scale multi-screen display device having a plurality of devices and operating each of the magnifying devices synchronously.

[Conventional technology]

2. Description of the Related Art Conventionally, a multi-screen display device, also called a multi-vision system, uses a magnifying process using a frame memory or the like of a magnifying device (video magnifying device) to convert video signals such as demonstration images of various events from video source devices such as LDP and VTR. The image signal is enlarged by 1 to N times in the horizontal and vertical directions to form an enlarged display video signal to be supplied to the multi-monitor device.

Then, the plurality of video monitors arranged in a matrix of the multi-monitor device display the video signal for the enlarged display on the screen to enlarge the video signal of the video source device, and display the demonstration image or the like on a large screen.

By the way, the enlargement processing is performed by executing image expansion data for display control including an enlargement ratio, a display position, and the like of each screen of the enlarged display, and this expansion data is used by a personal computer device (hereinafter, referred to as a PC device) or the like. It is formed by creating programming.

Then, the formed image development data is controlled online.
In the case of a configuration in which data is transferred from a PC device to an enlargement device and executed,
Due to restrictions such as the data transmission speed between the devices, a time lag easily occurs between the enlargement processing and the reproduction of the video source device.

 In addition, the PC device and the like must always be provided.

On the other hand, in the display of demonstration images or the like of various events, usually, the same video data is repeatedly executed to display an image of the same content in an enlarged manner, and the video data is rarely changed.

Therefore, for example, the document "Sanyo Technical Review (SA
NYO TECHNICAL REVIEW), VOL, 22, NO.2 (issued in June 1990), "Multi-Vision System" is provided with an execution control memory (execution program memory) having, for example, a RAM configuration in the enlargement device. It describes that the formed image development data is transferred to the execution control memory in advance by offline control, and after this transfer, the data in the execution control memory is executed to automatically operate the magnifying device to eliminate the above-mentioned inconvenience.

In addition, there is a large-scale type multi-screen display device that includes a plurality of the magnifying devices and the multi-monitor devices, and simultaneously operates the magnifying devices to simultaneously display the multi-monitor devices.

As described in the specification and the drawings of Japanese Patent Application No. 1-127330 (HO4N4 / 14), for example, the synchronous operation of a large-scale multi-screen display device may be performed by any one of the magnifying devices. One is set as a master device, and each of the remaining enlargement devices is set as a slave device.If necessary, a control signal for starting and stopping is simultaneously sent from the master device to each slave device via a common control signal line. The execution of each slave device is interrupted and resumed by an interrupt trigger based on the reception.

[Problems to be solved by the invention]

In the case of the conventional large-scale multi-screen display device, the master device unilaterally sends a start / stop control signal to each slave device to establish synchronization. Depending on the state of execution, the timing at which the trigger is received and the execution is interrupted and restarted is delayed from the timing at which the trigger is generated.

This delay causes a shift in the operation between the magnifying devices, and there is a problem that accurate synchronous operation cannot be performed.

Then, when the enlarged display is repeated, or the like, the deviation becomes large due to the repeated display, and the synchronous operation cannot be performed.

An object of the present invention is to provide a large-scale multi-screen display device capable of performing accurate synchronous operation.

[Means for solving the problem]

In order to achieve the above object, in the multi-screen display device of the present invention, while inserting an output command of a cue signal for synchronization establishment at a place where synchronization is performed in the middle of a series of video development data executed by the master device, An input wait command for the cue signal is inserted at a location to be executed prior to a cue signal output command for a series of video expansion data executed by each slave device, and the cue signal is executed by executing the output command in the mask device. Providing a master-side synchronization control unit that generates the following; a means for interrupting the execution of video expansion data by executing the input wait instruction in each of the slave devices; and an input of the cue signal connected to the master-side synchronization control unit. And a slave-side synchronization control unit for instructing cancellation of the interruption, wherein the interruption of each of the slave devices is canceled simultaneously by the cue signal.

[Action]

In the case of the multi-screen display device of the present invention configured as described above, when the cue signal is output from the master-side synchronization control unit of the master device based on the execution of the cue signal output command, each slave device waits for an input. Based on the execution of the instruction
The execution is always suspended and a queue signal is being input.

Then, the input of the queue signal causes the slave-side copper control unit of each slave device to immediately instruct the release of the interruption, and based on this command, the interruption of each slave device is released, and each slave device synchronizes with the input of the cue signal. And resume execution at the same time.

Therefore, the synchronization of the master device and each slave device is reliably established by the output command of the master device,
Accurate synchronous operation is performed.

Embodiment One embodiment will be described with reference to FIGS. 1 and 2. FIG.

In FIG. 1, (1) is a video source device including one or more video source devices such as LDP, VTR, etc., (2a) (2)
b),..., (2n) are a plurality of enlargement devices, each having an execution control memory (3) for holding video expansion data, an execution control unit (4) having a microcomputer configuration, and a synchronization control unit (5).

(6a), (6b), ..., (6n) and (7a), (7b),
, (7n) are a video switching device and a multi-monitor device provided for each of the enlargement devices (2a) to (2n), and each of the monitor devices (7a) to (7n) is a matrix of a plurality of video monitors (8). They are arranged and formed.

(9) is the creation and source device of video development data (1)
Is a system controller that controls the PC and the like, and is composed of a PC device and the like. (10) is a distributor for selectively supplying data of the system controller (9) to each of the enlargement devices (2a) to (2n).

In this embodiment, the enlargement device (2a) is set as a master device, and the remaining enlargement devices (2b) to (2n) are set.
Is set to the slave device.

Based on this setting, the synchronization control unit (5) of the enlargement device (2a) forms a master-side synchronization control unit, and the enlargement device (2b)
Each of the synchronization control units (5) to (2n) forms a slave-side synchronization control unit.

Then, the synchronization control unit (5) of the enlargement device (2a) is connected to the synchronization control unit (5) of each of the enlargement devices (2b) to (2n) via the synchronization signal line (11).

On the other hand, the video development data formed by the programming creation of the system controller (9) differs between the data of the master device and the data of the slave device even if the development contents are the same.

That is, a series of video development data executed by the master device is, for example, as shown in FIG. 2 (a), an output instruction of a cue signal for establishing synchronization at each synchronization point, that is, at each synchronization point. The "cue signal output" is inserted and formed.

A series of video expansion data executed by each slave device based on the respective video expansion data is, for example, as shown in FIG.
As shown in (1), a queue signal input wait instruction "queue signal wait" is inserted at a location to be executed prior to the queue signal output instruction, that is, immediately before the synchronization reestablishment location.

1, 10, 11, 12, and 13 in FIGS. 2A and 2B indicate program numbers (NO.) To be executed in order.

Then, the image development data for the formed master device,
The image development data for the slave device is transmitted from the system controller (9) via the distributor (10) to the execution control memory (5) of the enlargement device (2a) and the enlargement devices (2b) to (2) before operation.
It is downloaded and written to each of the execution control memories (5) of (n).

Further, when the download is completed, a start command is simultaneously given from the system controller (9) to the execution control unit (4) of each of the enlargement devices (2a) to (2n) via the distributor (10).

The operation of each of the magnifying devices (2a) to (2n) is simultaneously started by this start command, and thereafter, each magnifying control unit (4)
Automatically operates with an internal timer to perform automatic operation.

The system controller (9) performs device selection and playback control of the source device (1), and the video signal of the selected video source device is transmitted to each of the enlargement devices (2a) to (2n) and each of the video switching devices (6a). ) To (6n).

Then, in each of the enlargement devices (2a) to (2n), each execution control unit (4) reads out and executes the video expansion data in the memory (3), and based on the execution result, a frame memory configuration (not shown). Of the image line switching devices (6a) to (6n).

At this time, based on the control of the enlargement processing unit, the image signal supplied from the source device (1) to each of the enlargement devices (2a) to (2n) is subjected to enlargement processing, and an image signal for enlarged display is formed. It is supplied to the video switching devices (6a) to (6n).

In the case of enlarged display, the video switching devices (6a) to (6n)
Is switched from the output of the video signal of the source device (1) to the output of the video signal for enlarged display of each of the magnifying devices (2a) to (2n), and the video signal for enlarged display is changed to each of the monitor devices (7a) to
(7n), and a demonstration image or the like is enlarged and displayed on each of the monitor devices (7a) to (7n).

By the way, in order to insert, for example, a narrator's explanation (narration) in the middle of a demonstration or the like, in this embodiment, if the video development data is executed up to No. 11, "No. 11" in FIG. The execution control unit (4) of the magnifying device (2a) suspends the execution of the video development data due to "waiting for trigger".

In the same state as the enlargement device (2a), the execution of the image development data of the remaining enlargement devices (2b) to (2n) is interrupted. In order to establish synchronization when restarting and simultaneously restart the execution of the video expansion data of each of the magnifying devices (2b) to (2n), execution of "wait for queue signal" of No. 11 in FIG. Based on the above, the execution control unit (4) of each of the enlargement devices (2b) to (2n) also suspends the execution at the position of No. 11 of the respective video development data.

Then, each of the magnifying devices (2a) to (2n) waits for input of a cue signal, and each of the monitoring devices (7a) to (2a).
(7n) keeps displaying the screen just before the interruption.

Next, when the above explanation is completed and a restart trigger is given to the execution control unit (4) of the magnifying device (2a) based on a switch operation of the attendant, the control unit (4) executes the execution of the image development data. Resume.

At this time, the “queue signal output” of No. 12 in FIG. 2 (a) is executed first, and the respective enlargement devices are transmitted from the synchronization control unit (5) of the enlargement device (2a) via the synchronization signal line (11). (2b)
The cue signal is simultaneously provided to the synchronization control units (5) to (2n).

Based on this supply, in each of the enlargement devices (2b) to (2n), the synchronization control unit (5) immediately receives the cue signal, and the synchronization control unit (5) sends the cue signal to the execution control unit (4). A command for canceling the interruption corresponding to the trigger is given, and the execution control unit (4) resumes the execution of the respective image development data.

Then, each magnifying device (2
b) to (2n) simultaneously resume the execution of the respective video development data, and the "enlarged memory setting" of No. 12 in FIG.
Do first.

At this time, in the magnifying device (2a) as well, FIG.
NO.13 “Enlargement memory setting” is executed, and each enlargement device (2
a) to (2n) simultaneously execute the first instruction of the enlargement processing immediately after resuming to perform synchronization.

By this synchronization, the operation of each of the magnifying devices (2a) to (2n) is restarted in a completely synchronized state, and accurate synchronized operation is performed.

Then, at each point where the video expansion data of the enlargement device (2a) is resynchronized, the "cue signal output" of No. 12 in FIG. 2A is inserted, and the video expansion data of the remaining enlargement device (2b) is inserted. The "queue signal wait" of No. 11 in FIG. 11B is inserted for each location executed before the "queue signal output", and the same synchronization as described above is performed.

By the way, in the above-mentioned embodiment, each magnifying device (2a)
To (2n) are provided with an execution control memory (3). After startup, each of the magnifying devices (2a) to (2n) performs processing by automatic operation without being controlled by the system controller (9). There is no time lag between the video signal output from (1) and the processing of each of the enlargement devices (2a) to (2n).

〔The invention's effect〕

Since the present invention is configured as described above,
The following effects are obtained.

When the cue signal is output from the master-side synchronization control unit of the master device based on the execution of the cue signal output instruction,
Based on the execution of the command waiting for input, each slave device always interrupts the execution of its own video expansion data and is in a state of waiting for the input of a cue signal, so the slave-side synchronization control unit of each slave device is immediately interrupted. Command, and based on this command, each slave device restarts the execution of the respective video expansion data simultaneously in synchronization with the input of the cue signal, and by executing the output command of the master device, the master device and the Synchronization of each slave device is established, and accurate synchronous operation of this kind of large-scale multi-screen display device that performs enlarged display by a plurality of multi-monitor devices is realized.

[Brief description of the drawings]

FIG. 1 is a block diagram of an embodiment of a multi-screen display device according to the present invention, and FIGS. 2 (a) and 2 (b) are explanatory diagrams of image development data of the master device and each slave device in FIG. (1) ... video source device, (2a) ... magnifying device set as master device, (2b), (2n) ... magnifying device set as slave device, (5) ... synchronization control unit, (7a),
(7b), (7n): Multi-monitor device, (8): Video monitor.

Continuing from the front page (72) Inventor Nobuo Kuchi 2-18-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Inventor Motoaki Asao 2--18-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric (56) References JP-A-2-59795 (JP, A) JP-A-63-151992 (JP, A)

Claims (1)

(57) [Claims] 1. A master device for setting one of a plurality of magnifying devices to which a video signal from a video source device is supplied, and setting each of the remaining magnifying devices to a slave device. The operation of the slave device is controlled to synchronously operate the magnifying devices. The magnifying devices execute video expansion data for each display control, and magnify and process the video signal of the source device for magnified display. A multi-screen display device for forming a video signal of the same, supplying the video signal to each video monitor arranged in a matrix of each multi-monitor device, and enlarging and displaying the video signal of the source device by each video monitor, While inserting a cue signal output command for synchronization establishment at a place where synchronization is performed in the middle of a series of video development data executed by the master device, The queue device inserts a queue signal input wait command at a location to be executed prior to the cue signal output command of each series of video expansion data executed by the slave device, and the mask device executes the output command to execute the output command. Providing a master-side synchronization control unit that generates a cue signal, a means for interrupting the execution of video expansion data by executing the input wait instruction in each of the slave devices, and a cue signal connected to the master-side synchronization control unit. A multi-screen display device, comprising: a slave-side synchronization control unit that instructs cancellation of the interruption by an input; and cancels the interruption of each of the slave devices simultaneously by the cue signal.