KR100818238B1 - Multi-display circuit system - Google Patents

Abstract

A multivision circuit system is provided to prevent a loss of picture quality in spite of using a plurality of displays and display a uniform image by taking uniform white balance on each display screen image. An image standard conversion circuit(100) receives various standards of analog or digital video signals, converts a signal selected from the various standards of video signals into an optimum digital video signal and outputs the same. Only the optimum digital video signal outputted from the image standard conversion circuit(100) is inputted to a plurality of display circuits(200A,200B,200C,200D) and displayed. The image standard conversion circuit(100) includes a receiving/converting unit for receiving various standards of analog or digital video signals, converting an analog video signal into a digital video signal, and outputting each digital video signal, a selecting unit for selecting one of the digital video signals outputted from the receiving/converting unit and outputting the same, an output converting unit for converting the digital video signal selected by the selecting unit into an optimum digital video signal and outputting the same, and a controller for controlling each function part.

Description

Multi-vision circuit system

1 is a block diagram showing a conventional multi-vision circuit system.

2 is a block diagram showing a multi-vision circuit system according to an embodiment of the present invention.

3 is a block diagram of an image standard conversion circuit according to an embodiment of the present invention.

4 is a block diagram of a display circuit according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multivision circuit system, and more particularly, to a multivision circuit system in which all video signals are converted into one optimal digital video signal at an input terminal and only one distribution circuit is used in each display circuit.

1 is a block diagram of a conventional multi-vision circuit system.

As shown in FIG. 1, the conventional multi-vision system is a system for distributing transmission to other display circuits by using distribution circuits for all image signals in each display circuit.

Therefore, there is a problem that a lot of parts, wiring is complicated, and failure occurs frequently.

In addition, in the case of selecting analog video signals (Analog RGB, Composite, S-Video, Component), there is a problem that image quality damage accumulates while the analog video signals are repeatedly routed through the distribution circuit and through the wiring.

In addition, when the analog video signal is selected, the analog video signal is converted into a digital signal for each display circuit, so that the white balance of each display screen is different, thereby uniformly representing the image quality of each display screen. There is no problem.

In order to solve the above-mentioned problems of the prior art, the present invention converts all video signals into one optimal digital video signal at an input terminal of a multi-vision so that each display circuit uses only one distribution circuit and the optimal digital video signal is continuously transmitted. Accordingly, an object of the present invention is to provide a multi-vision circuit system capable of showing a small number of parts, a simple wiring, no loss of image quality, and a uniform image.

In addition, another object of the present invention is to provide a multi-vision circuit system capable of instantaneously displaying the same or different still images on each display screen.

The multivision circuit system of the present invention for solving the above technical problem,
A multi-vision circuit system for processing a multi-vision video signal, comprising: receiving an analog or digital video signal of various standards, and converting a video standard from an image signal of the various standards into an optimal digital video signal and outputting the video standard; Standard conversion circuit; And a plurality of display circuits, wherein only the optimum digital image signals output from the image standard conversion circuit are input to the plurality of display circuits and displayed.
In this case, the optimal digital video signal is a DVI signal.
The image standard conversion circuit may further include: a reception conversion unit configured to receive analog or digital video signals of various standards, and the analog video signals are converted into digital video signals and then output respective digital video signals; A selection unit which selects and outputs one of the respective digital image signals output from the reception conversion unit; An output converter converting the video standard of the digital video signal selected by the selector into an optimal digital video signal and outputting the optimal digital video signal; And a control unit for controlling the respective functional units.
The image standard conversion circuit may further include a memory configured to store a digital image signal; And a memory controller configured to store the digital video signal selected by the selector in the memory on a frame basis and to read the data stored in the memory on a frame basis and output the data to the output converter.
The display circuit may include a distribution circuit for distributing the optimal digital video signal, receiving the optimal digital video signal, and distributing the optimal digital video signal to another display circuit through the distribution circuit. .
The display circuit may include a receiver configured to receive the optimal digital video signal; A transmitter for transmitting the optimum digital video signal received by the receiver to another display circuit; A memory for storing a digital video signal; A memory controller configured to store the digital image signal received from the receiver in the memory in a frame unit and to read the data stored in the memory in a frame unit and output the data to an interface unit; An interface unit for transmitting the digital image signal received from the memory controller to a display device; And a control unit for controlling the respective functional units.
The display circuit may further include a scaling unit that adjusts an input image to a desired resolution, and preferably includes a dip switch that sets coordinate values of the plurality of display modules.
The reception converting unit may include an A / D converter which receives an analog RGB signal and converts the analog RGB signal into a digital signal; DVI Rx for receiving a DVI signal; And a video decoder which receives a composite signal, an S-video signal, and a component signal, selects one of the signals and converts the signal into a digital video signal. .
The output converter may further include an output formatter configured to convert the digital video signal received from the memory controller into the optimal digital signal format; And a transmitter configured to output a digital video signal output from the output formatter as an optimal digital signal.

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As a result, the present invention converts all video signals into one optimal digital video signal at an input terminal, and since only the optimal digital video signals are transmitted to each display circuit, there is almost no loss of image quality even when using a plurality of displays. Uniform white balance can be obtained every time, resulting in a uniform image.
In addition, since only one optimal digital video signal can be sequentially transmitted through each display circuit, only one distribution circuit can be used in each display circuit, so that multi-vision with low component count, simple wiring, and low failure rate can be achieved. Can provide.

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On the other hand, the display circuit of the present invention for displaying the instantaneous still image on each display screen, the display circuit for operating each display module of the multi-vision, the receiving unit for receiving a video signal; A transmitter for transmitting the image signal received by the receiver to another display circuit; A memory for storing a digital video signal; A memory controller configured to store the digital video signal received by the receiver in the memory in a frame unit and to read the data stored in the memory in a frame unit and output the data to an interface unit; An interface unit for transmitting the digital video signal output from the memory controller to a display device; A control unit controlling the respective function units; And a switching unit configured to block and connect an image signal stored in the memory from the memory controller by the controller.

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As a result, the same or different still images may be instantaneously displayed on each display screen.

When described in detail by the accompanying drawings an embodiment of the present invention as follows. Like reference numerals in the drawings denote components that perform the same function.

2 is a block diagram showing a multi-vision circuit system according to an embodiment of the present invention.

The multi-vision circuit system of the present invention is composed of an image standard conversion circuit 100 and a plurality of display circuits 200A, 200B, 200C, 200D. The display circuits 200A, 200B, 200C, and 200D are circuits embedded in each display device (LCD, PDP, CRT, etc.) constituting the multivision, and the image standard conversion circuit 100 may be embedded in the multivision. It can also be designed externally.

The video standard conversion circuit 100 receives various video signals (Analog RGB, DVI, Composite, S-Video, Component) from video signal input sources (DVD, VTR, STB, etc.), and the analog video signals are digital. After converting to a video signal, it is a circuit that selects one of the digital video signal to convert the video standard to an optimal digital video signal (DVI) to output.

In addition, the display circuits 200A, 200B, 200C, and 200D are circuits for receiving an optimal digital video signal DVI, outputting the same to a corresponding display device, and distributing and transmitting the optimal digital video signal DVI to another display circuit. .
The multi-vision circuit system of the present invention is characterized in that only the optimal digital video signal output from the video standard conversion circuit is input to the plurality of display circuits for display.
For example, as shown in FIG. 2, in the multi-vision circuit system of the present invention, an optimal digital image signal may be output from the image standard conversion circuit and sequentially passed to each display circuit while passing through each display circuit. In detail, various image signals are input to the image standard conversion circuit 100, and only one of these signals is selected to convert the image standard into a DVI signal and output the first and second display circuits 200A. ) Outputs a DVI signal to the display circuit 200B via an internal DVI distribution circuit. In this way, DVI video signals are delivered to all display circuits.
DVI is a technology that defines the standard of image information. By using this, one hour of video (video) data can be stored on a single disk, and a very high quality image can be realized and stable signal transmission is possible.
In the present invention, a signal selected from video signals of various standards inputted by the video standard conversion circuit is converted into a DVI signal which is an optimal digital video signal, and only such DVI signal is transmitted to each display circuit, so that an analog signal such as an RGB signal Compared to the case where the signal transmission is more stable, it is possible to implement a high quality image.

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In the present embodiment, the DVI signal is transmitted as the optimum digital video signal. However, the present invention is not limited thereto and may be used as the optimal digital video signal of the present invention as long as it is a digital video signal standard in which reliability of compression or image quality is guaranteed.

As described above, the present invention converts all video signals into one optimal digital video signal at the input stage, and then only the optimal digital signals are transmitted to each display circuit, so that only one distribution circuit can be used in each display circuit. In this way, it is possible to provide multivision with a low component count, simple wiring, and a low failure rate.
In addition, since all the video signals are delivered only the optimal digital video signal after the input stage, there is almost no loss of image quality even when multiple displays are used, and uniform white balance can be obtained for each display screen so that a uniform image can be displayed. do.

Hereinafter, the configuration and operation of the image standard conversion circuit according to an embodiment will be described in detail. 3 is a block diagram of an image standard conversion circuit according to an embodiment of the present invention.

As shown in FIG. 3, the image standard conversion circuit 100 includes a reception conversion unit 111, 113, and 115, a selection unit 120, a memory 130, a memory control unit 140, and an output conversion unit 150. , 160, and a controller 170 for controlling each functional unit.

The reception converters 111, 113, and 115 respectively receive various video signals (Analog RGB, DVI, Composite, S-Video, Component), and among them, analog signals (Analog RGB, Composite, S-Video, Component). Is converted into a digital video signal and output to the selector 120.

The selector 120 selects one of the digital video signals received from the reception converters 111, 113, and 115 and outputs the selected ones to the memory controller 140.

The memory controller 140 stores the digital image signal received from the selector 120 in the memory 130 in units of frames, reads the data stored in the memory 130 in units of frames, and outputs the data to the output converters 150 and 160. The memory 130 stores the digital video signal in units of frames.

The output converters 150 and 160 convert the video standard of the digital video signal received from the memory controller 140 into an optimal digital video signal DVI and output the converted video standard.

The controller 170 receives a control signal from a PC or the like and controls each of the above-described functional units.

The above-described reception converters 111, 113, and 115 may include an A / D converter 111 for receiving an analog RGB signal and converting it into a digital signal, a DVI Rx 113 for receiving a DVI signal, a composite signal, The video decoder 115 may be configured to receive an S-video signal and a component signal, and to select one of the signals and convert the signal into a digital video signal.

The selector 120 is preferably configured as a multiplexer, and a memory of 256 Mb DDR RAM is used as an embodiment.

In addition, the above-described output converters 150 and 160 are provided from an output formatter 150 and an output formatter 150 for converting a digital video signal received from the memory controller 140 into a 24-bit TTL signal. It may be configured to include a DVI Tx (160) for outputting the received digital video signal as a DVI signal.

Control signal is generally used communication port RS 422, communication signal is usually generated from PC and coordinate value and command are generated. Commands include signals for zoom, real, still, coordinates, screen selection, and other multivision controls. The communication signal is applied to both the image standard conversion circuit 100 and the display circuits 200A, 200B, 200C, and 200D.

Hereinafter, the configuration and operation of the display circuit according to an embodiment will be described in detail. 4 is a block diagram of a display circuit according to an embodiment of the present invention.

As shown in FIG. 4, the display circuit 200 includes a receiver 210, a transmitter 260, a memory 230, a memory controller 250, a controller 270, and an interface unit 280. It is composed.

The receiver 210 receives the DVI signal and outputs the DVI signal to the memory controller, and the transmitter 260 transmits the DVI signal to another display circuit.

The memory controller 250 stores the digital video signal received from the receiver 210 in the memory 230 in units of frames, reads the data stored in the memory 230 in units of frames, and outputs the data to the interface unit 280. 230 stores the digital video signal in units of frames.

The interface unit 280 transmits the digital image signal received from the memory controller 250 to the display module 300 such as LCD, PDP, CRT, etc., and the controller 270 controls each of the above-described functional units according to the control signal. .

In the present embodiment, the receiver 260 is configured by DVI Rx, the transmitter 260 is configured by DVI Tx, and the interface unit 280 is preferably configured by LVDS Tx.

In addition, the display circuit further includes scaling units 220 and 240 for adjusting the input image to a desired resolution. In the present embodiment, the shrink unit 220 and the zoom unit 240 are configured before and after the memory control unit 250. The shrink unit 220 reduces the resolution when the video signal is larger than the desired resolution and outputs it unchanged when it is smaller than or equal to the zoom signal. The zoom unit 240 enlarges the resolution when the video signal is smaller than the desired resolution. Output to (280).

In addition, the display circuit may include a dip switch (not shown) for setting the coordinate value of the display module, thereby selecting and outputting a desired display.

On the other hand, the display circuit of the present invention has a technical configuration that can display the same or different still image instantaneously on each display screen.

That is, as shown in FIG. 3, the switching unit may block and connect the video signal stored in the path in which the video signal is stored from the memory controller 250 to the memory 230. The blocking and connection of the video signal stored in the memory 230 are controlled by the control unit 270 by the control signal.

When the video signal stored in the memory 230 is cut off from the memory controller 250 by the switching unit, the new video signal is no longer input to the memory 230, so that the display circuit continuously outputs the frame stored in the memory. As a result, the still image is continuously output. In this state, when the switching unit is connected again and the new video signal is stored in the memory again, new successive images are displayed on the screen.

Each display circuit 200A, 200B, 200C, 200D can control the switching unit, so that only a part of each display screen can be displayed still image, each display screen not only the same still image but also different still image You can also make it appear.

As described above, an optimal embodiment has been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

The multi-vision circuit system of the present invention described above converts all video signals into one optimal digital video signal at an input terminal, and each display circuit uses only one distribution circuit, so that the number of components is small, the wiring is simple, and the failure rate is low. Can be provided.

In addition, since all video signals are transferred to the optimal digital video signal after the input stage, there is almost no loss of image quality even when using a plurality of displays, and uniform white balance can be obtained for each display screen, thereby providing a uniform image. .

In addition, by configuring the switching unit for blocking and connecting the video signal stored in the memory from the memory control unit in each display circuit, it is possible to provide a multi-vision that can show the same or different still image on each display screen.

Claims (12)

A multi-vision circuit system for processing multi-vision video signals, A video standard conversion circuit for receiving analog or digital video signals of various standards, and converting a video standard from an image signal of the various standards into an optimal digital video signal and outputting the converted video standard; And A plurality of display circuits; Including, And the optimum digital video signal outputted from the video standard conversion circuit is input to the plurality of display circuits for display. The method according to claim 1, The image standard conversion circuit, A reception converting unit for receiving analog or digital video signals of various standards, the analog video signals being converted into digital video signals and outputting respective digital video signals; A selection unit which selects and outputs one of the respective digital image signals output from the reception conversion unit; An output converter converting the video standard of the digital video signal selected by the selector into an optimal digital video signal and outputting the optimal digital video signal; And A control unit controlling the respective function units; Multi-vision circuit system comprising a. The method according to claim 2, The image standard conversion circuit, A memory for storing a digital video signal; And A memory controller configured to store the digital video signal selected by the selector in the memory on a frame basis and to read and output the data stored in the memory on a frame basis; Multi-vision circuit system, characterized in that further comprises. The method according to claim 1, The display circuit, A distribution circuit for distributing the optimal digital video signal, And receiving the optimal digital video signal and distributing the optimal digital video signal to another display circuit through the distribution circuit. The method according to claim 1, The display circuit, A receiver which receives the optimal digital video signal; A transmitter for transmitting the optimum digital video signal received by the receiver to another display circuit; A memory for storing a digital video signal; A memory controller configured to store the digital image signal received from the receiver in the memory in a frame unit and to read the data stored in the memory in a frame unit and output the data to an interface unit; An interface unit for transmitting the digital image signal received from the memory controller to a display device; And A control unit controlling the respective function units; Multi-vision circuit system, characterized in that comprises a. The method according to claim 5, The display circuit, A scaling unit for adjusting the input image to a desired resolution; Multi-vision circuit system further comprising. The method according to claim 1, The display circuit, A multi-vision circuit system comprising a dip switch for setting the coordinate values of the plurality of display modules. The method according to claim 1, The optimal digital video signal is a multi-vision circuit system, characterized in that the DVI signal. The method according to claim 2, The reception converting unit, An A / D converter which receives an analog RGB signal and converts it into a digital signal; DVI Rx for receiving a DVI signal; And A video decoder which receives a composite signal, an S-video signal, and a component signal, selects one of the signals, and converts the signal into a digital video signal; Multi-vision circuit system comprising a. The method according to claim 2, The output converter, An output formatter for converting the digital video signal received from the memory controller into the optimal digital signal format; And A transmission unit which outputs the digital video signal received from the output formatter as an optimal digital signal; Multi-vision circuit system comprising a. A multi-vision input stage circuit for receiving a video signal and transmitting it to a display module, A reception converting unit for receiving analog or digital video signals of various standards, the analog video signals being converted into digital video signals and outputting respective digital video signals; A selection unit which selects and outputs one of the respective digital image signals output from the reception conversion unit; A memory for storing a digital video signal; And A memory controller configured to store the digital video signal selected by the selector in the memory on a frame basis and to read and output the data stored in the memory on a frame basis; An output converter for converting the video standard of the digital video signal output from the memory controller into an optimal digital video signal; And A control unit controlling the respective function units; An image standard conversion circuit comprising a. A display circuit for operating each display module of the multivision, A receiver for receiving an image signal; A transmitter for transmitting the image signal received by the receiver to another display circuit; A memory for storing a digital video signal; A memory controller configured to store the digital video signal received by the receiver in the memory in a frame unit and to read the data stored in the memory in a frame unit and output the data to an interface unit; An interface unit for transmitting the digital video signal output from the memory controller to a display device; A control unit controlling the respective function units; And A switching unit configured to block and connect an image signal stored in the memory from the memory controller by the controller; Display circuit comprising a.

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