KR20070080320A - Apparatus and method for transferring a monitoring image - Google Patents

Abstract

The present invention relates to a video surveillance system, and more particularly, to an apparatus capable of transmitting split-screen images required by each client while minimizing loss of video for a channel to be monitored.

An A / D converter for converting each of the plurality of camera images into digital data; A screen reconstruction unit for reconstructing camera images of each channel converted into digital data into at least one n-split screen requested by each client; And encoders for encoding each of the one or more n-split screens and outputting the encoded data to an external device.

Description

Surveillance video transmission device and its method {APPARATUS AND METHOD FOR TRANSFERRING A MONITORING IMAGE}

1 is an exemplary configuration diagram of a general video surveillance system.

2 is an exemplary diagram of a video surveillance system including a surveillance video transmission apparatus according to an embodiment of the present invention.

3 is a detailed configuration example of the screen reconstruction unit 213 of FIG. 2.

The present invention relates to a video surveillance system, and more particularly, to an apparatus and method for transmitting surveillance video.

In general, the most commonly used system for monitoring the occurrence of abnormal phenomena such as theft or intrusion accidents at specific places is the video surveillance system using cameras and monitors.

Such a video surveillance system is a structure in which a CCTV camera is installed at a specific location, a specific object or a specific location, and a subject is captured by the camera to display a screen captured by the monitor. It is used to determine the abnormality through the screen.

As an advanced form of the video surveillance system, recently, a system for transmitting a desired channel image to each client through a video server has been introduced. One example of such a system is shown in FIG.

The video surveillance system shown in FIG. 1 is largely composed of an image transmission apparatus including a camera 100, a channel selector 110, and an encoder 120, and a client 140 of multi-channel camera images transmitted from the image transmission apparatus. ) Can be divided into a video server 130 which extracts only an image of a desired channel and provides it to each client 140, and a client 140 which processes and displays an image provided from the video server 130. At this time, the client 140 refers to a client terminal such as a PC.

Each of the cameras 100 constituting the image transmission apparatus photographs and outputs an image of a designated place, and the channel selector 110 sequentially selects and outputs camera images input from the 16 channels. The encoder 120 located at the rear end encodes a camera image output from the channel selector 110 and outputs the image to the video server 130.

In the system having the above-described configuration, since 16 channel images are sequentially encoded by the channel selector 110, the number of frames of each channel transmitted to the video server 130 may be limited. For example, if the encoder 120 is capable of encoding 160 frames per second, in the above-described system, only 10 frames per second for each channel are encoded and transmitted to the video server 130, resulting in a critical video. The problem arises that the loss of.

Accordingly, an object of the present invention is to provide a surveillance video transmission apparatus and method for transmitting the divided screen images required by each client while minimizing the loss of the video for the surveillance channel.

Surveillance image transmission apparatus according to an embodiment of the present invention for achieving the above object,

An A / D converter for converting each of the plurality of camera images into digital data;

A screen reconstruction unit for reconstructing camera images of each channel converted into digital data into at least one n-split screen requested by each client;

And encoders for encoding each of the one or more n-split screens and outputting the encoded data to an external device.

Furthermore, the screen reconstruction unit in the device,

Input image memories for storing a camera image of each channel converted into digital data for each channel;

Output image memories for storing and outputting camera image data constituting an n-split screen requested by each client;

And a divider processor configured to read and resize the camera image necessary for configuring the n-split screen requested by each client from the input image memory, and to distribute the image to the output image memory.

According to the characteristics of the present invention as described above, by reconstructing and encoding the n-split screen requested by each client in advance and transmitting it to an external device such as a video server, each client receives the n-split screen without frame loss You can see it.

Furthermore, the surveillance video transmission method according to another embodiment of the present invention,

Receiving and storing a plurality of camera images through different channels;

Reading a camera image necessary for configuring an n-split screen requested by each client among a plurality of stored camera images and reconfiguring the split-screen into client-specific split screens;

Encoding the reconstructed split screens for each client;

And transmitting the encoded divided screens for each client to the video server.

This method also reconstructs and encodes the n-split picture requested by each client in advance, and transmits it to an external device such as a video server, so that each client can receive the n-split picture without frame loss.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, a detailed description of related known functions or configurations will be omitted.

First, FIG. 2 illustrates a configuration of a video surveillance system including a surveillance video transmission apparatus 210 according to an embodiment of the present invention, and FIG. 3 illustrates a detailed configuration diagram of the screen reconstruction unit 213 of FIG. 2. It is illustrated.

2, each of the cameras 200 captures and outputs an image of a designated place. The output camera video signal may be assumed to be an analog NTSC signal.

The surveillance image transmission device 210 positioned at the rear of the camera 200 reconstructs the camera images, which are outputs of the cameras 200, into n-split screens required by each client, and then encodes and outputs them.

As shown in FIG. 2, the surveillance image transmitting apparatus 210 includes an A / D converter 211 for converting each of the plurality of camera 200 images into digital data, and a channel of each channel converted into digital data. A screen reconstruction unit 213 for reconstructing camera images into one or more n-split screens requested by each client, and encoders for encoding each of the one or more n-split screens and outputting them to an external device such as a video server 220. (215, 217, 219).

For reference, the n-split screen requested by the client may be any one of a 4-split screen, a 6-split screen, a 9-split screen, a 10-split screen, and a 16-split screen. This is only an example, and the configuration of the n-split screen may be required for each client differently.

Meanwhile, the video server 220 provides each client 230 with an n-split screen for each client output from the video transmission apparatus. In addition, the video server 220 may receive an n split screen configuration request from each client and transmit a command corresponding thereto to the surveillance video transmission apparatus 10. The video server 220 and the surveillance video transmission apparatus may mutually transmit the n-split screen and the necessary control command for each client through a dedicated line such as an E1 network.

Finally, each client 230 is a terminal that receives and displays the n-split screen provided to it by the video server 220.

Hereinafter, a detailed configuration of the screen reconstruction unit 213 will be described in detail with reference to FIG. 3.

As illustrated in FIG. 3, the screen reconstruction unit 213 may include channel-specific input image memories 213a 213b and 213c, a plurality of output image memories 213e, 213f and 213g, and a divider processor 213d. It includes. In some cases, the control command receiver 213h may be further included.

Each of the input image memories 213a 213b and 213c for each channel constituting the screen reconstruction unit 213 stores a camera image of each channel converted into digital data by the A / D converter 211 for each channel. ,

Each of the output image memories 213e, 213f, and 213g stores and outputs camera image data constituting the n-split screen requested by each client. The output image memories 213e, 213f, and 213g may be referred to as frame memories.

The divider processor 213d reads out the camera image required for configuring the n-split screen requested or programmed by each client from the input image memories 213a, 213b, and 213c, and adjusts the size of the camera image. 213e, 213f, and 213g). Since adjusting the horizontal and vertical size of each camera image according to the number of split screens is a technique well known in the art, a detailed description thereof will be omitted.

The control command receiving unit 213h, which can be added in some cases, plays a role of receiving a command for requesting n-split screen configuration of each client from the video server 220 and authorizing it to the processor 213d.

Hereinafter, the operation of the surveillance image transmission apparatus 210 including the screen reconstruction unit 213 having the above-described configuration will be described.

First, an analog camera image output from each camera 200 is converted into a digital image by the A / D converter 211 and output. For example, it may be assumed that the camera image output from the A / D converter 211 is a YUV422 type signal having a 360 * 240 size, and 30 frames per second (FPS) are output for each channel.

The camera image converted into a digital image for each channel is temporarily stored in the input image memories 213a, 213b, and 213c in the screen reconstruction unit 213.

On the other hand, the divider processor 213d reads out and adjusts a size of a camera image from the input image memories 213a, 213b, and 213c that are required for configuring the n-split screens requested by each client or programmed for each output channel. For example, if the size of the output video memories 213e, 213f, and 213g is 720 * 480, size adjustment is not necessary when configuring the 4-split screen, but when configuring the 9-split screen, the original camera image having a 360 * 240 size Reduce the size to fit (720 * 480) / 3. When the size adjustment is made to fit the n-split screen ratio, the divider processor 213d distributes and stores the resized camera image in the designated output image memories 213e, 213f, and 213g to produce one frame image divided by n. do.

In this way, the n-split screens for each output channel generated by the client request are respectively encoded by the corresponding encoders 215, 217, and 219, and then transmitted to the video server 220 through the designated communication socket. Accordingly, the video server 220 may provide the n-split screens transmitted from the surveillance video transmission apparatus 210 to each of the clients 230 requesting the split screen.

According to the operation of the present invention as described above, by reconstructing and encoding the n-split screen requested by each client in advance in the surveillance video transmission apparatus 210 and transmits it to an external device such as a video server, each client is a frame You can receive the n-split screen without any loss.

As described above, the present invention reconstructs and encodes the n-split screen requested by each client in advance, and transmits the encoded data to an external device such as a video server, thereby minimizing the loss of video for the channel to be monitored. It will have the advantage of transmitting images of one split screen.

On the other hand, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only by the appended claims.

Claims (4)

In the surveillance video transmission device, An A / D converter for converting each of the plurality of camera images into digital data; A screen reconstruction unit for reconstructing camera images of each channel converted into digital data into at least one n-split screen requested by each client; And at least one encoder for encoding each of the n-split screens and outputting the encoded data to an external device. The method of claim 1, wherein the screen reconstruction unit, Input image memories for storing a camera image of each channel converted into digital data for each channel; Output image memories for storing and outputting camera image data constituting an n-split screen requested by each client; And a divider processor for reading and resizing the camera image necessary for configuring the n-split screen requested by each client from the input image memory and distributing and storing the image in the output image memory. . The apparatus of claim 2, further comprising a control command receiver configured to receive a command for requesting n-split screen configuration of each client and apply the same to the processor. In the surveillance video transmission method, Receiving and storing a plurality of camera images through different channels; Reading a camera image necessary for configuring an n-split screen requested by each client among a plurality of stored camera images and reconfiguring the split-screen into client-specific split screens; Encoding the reconstructed split screens for each client; And transmitting the encoded divided screens for each client to the video server.

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