JP2006166476A - Method for transmitting image - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the trouble wherein all the compressed data can not be processed due to the limit of a transmission capacity on a reception side, and contents of received camera video images can not be confirmed in the case where a plurality of the camera video images are compressed and transmitted to a network. <P>SOLUTION: In a compressed image transmitter wherein a plurality of transmitters for which a camera and an encoder compressing the camera video images are one set, and a plurality of receivers for which a decoder expanding the compressed data, a monitor, and a console are one set, are connected to the network, the respective reference screen data corresponding to a plurality of the camera video images are transmitted by using a part of the transmission capacity of the network. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an improvement in a system in which a plurality of moving image compression devices and a moving image data display device are combined.

  In recent years, image processing technology, particularly compression technology for image information and audio information, has made remarkable progress, and it has become possible to transmit high-quality moving images and audio even with a transmission path having a small capacity. For example, in an application for monitoring the state of a subject in a remote place via a network, a high-quality moving image can be transmitted in combination with a moving image data compression device even on a transmission path with a small data transmission capacity. . Also, by using the image compression technique, it has become possible to transmit a plurality of moving image data to a transmission path having a data transmission capacity that can conventionally only transmit one moving image.

  For example, a configuration in which a plurality of moving image data compression devices are connected to a network, image compression processing is performed on a moving image captured by a camera, and the image is transmitted to the network is used for applications such as remote monitoring. A plurality of compressed moving image data transmitted by compressing the camera video to the network is decompressed by the moving image data decompression device in the receiving terminal connected to the same network and displayed on the monitor screen.

FIG. 2 shows a configuration example of a compressed image transmission apparatus in which a plurality of moving image data compression apparatuses and receiving terminals are connected to a network.
On the transmission side, a camera that outputs video data and an encoder that compresses video data are used as a unit, and a plurality of these combinations are connected to the network. In this example, combinations having three cameras, cameras 1-1, 1-9, and 2-3, are connected to the network 1-25, respectively.

  The encoder 2-1 performs image compression processing on the video signal 1-2 output from the camera 1-1. The compressed data 1-4 output from the encoder 2-1 is output to the network 1-25.

  Similarly, the video signal 1-10 output from the camera 1-9 is subjected to image compression processing by the encoder 2-2, output to the network 1-25 as compressed data 1-12, and output from the camera 2-3. The video signal 2-4 is subjected to image compression processing by the encoder 2-5, and is output to the network 1-25 as compressed data 2-6. The above is the configuration on the compressed data transmission side.

  Next, on the receiving side, a combination of a decoder that performs decompression processing of compressed data and a monitor is used as a unit, and a plurality of such combinations are connected to the network. In this example, one combination of the decoder 1-27 and the monitor 1-31 is connected.

  The decoder 1-27 takes in one of the three compressed data connected to the network 1-25 as the compressed data 1-26, and performs image expansion processing. The expanded image data is output to the monitor 1-31 as a video signal 1-28.

  The console 1-32 is installed in order to switch the camera image while viewing the image on the monitor 1-31. In this example, three cameras are connected to the transmission side, but the console can select which of these cameras is displayed on the monitor 1-31. When selecting a camera on the console 1-32, a camera selection signal 1-33 is output to the compressed data selector 1-34. The compression data selector 1-34 determines which camera video data has been selected by the console 1-32 from the contents of the camera selection signal 1-33, and selects the compression data corresponding to the camera. Data selection signal 1-35 is output to decoder 1-27.

Next, the operation of the compressed image transmission apparatus in which a plurality of moving image data compression apparatuses and a receiving terminal in FIG. 2 are connected to a network will be described.
The video signal 1-2 output from the camera 1-1 is subjected to image compression processing by the encoder 2-1.

  In this image compression processing, digital processing is performed on the video signal, and redundant data of the image is deleted to reduce the data size. For this reason, the image quality is hardly deteriorated when the image after image compression is viewed. If information is deleted to further reduce the data size, visible degradation occurs in the image. However, since the degradation takes into account the characteristics of the human eye, it feels slight degradation such as blurring of the detailed representation of the image, but it does not cause degradation that makes it difficult to know what the image shows. .

The video signal 1-2 that has been subjected to image compression processing by the encoder 2-1 and whose data size has been reduced is output as compressed data 1-4 to the network 1-25.
Similarly, video data 1-10 output from the camera 1-9 is output as compressed data 1-12 by the encoder 2-2, and video data 2-4 output from the camera 2-3 is output by the encoder 2-5. Output as compressed data 2-6.

As a result, three moving image compressed data of the compressed data 1-4, the compressed data 1-12, and the compressed data 2-6 are input to the network 1-25.
Since the data transmission capacity of the network 1-25 is finite, the three compressed data must be controlled so that the sum of the data does not exceed the transmission capacity.

  Therefore, when performing the image compression process, the three encoders connected to the network each perform the image compression process so that the compressed data size does not exceed the transmission capacity of the network. Here, when the three encoders are connected to the network 1-25 as in this example, the simplest implementation method is to set the transmission capacity of 1/3, which is a value obtained by equally dividing the transmission capacity of the network. This is to limit the transmission capacity of compressed data generated by one encoder. Since the transmission capacity of the network is determined, the restriction on the transmission capacity of the compressed data generated by each encoder can be derived from the number of encoders connected to the network 1-25. If the transmission capacity of the network is equally divided by the number of cameras, the maximum transmission capacity that can be allocated to one compressed data is obtained.

  In order to perform image compression processing so that the camera image does not deteriorate, it is desirable to increase the size of the compressed data as much as possible. Therefore, the image compression process is performed so that the compressed data size can be used up to the limit of the transmission capacity. The above is the operation on the transmission side.

  On the receiving side, the decoder 1-27 connected to the network 1-25 takes in the compressed data 1-4, 1-12, or 2-6 transmitted over the network 1-25, and the image Perform decompression processing. Which compressed data is taken depends on the compressed data selection signal 1-35.

  The decoder 1-27 performs a decompression process for returning the captured compressed data to the original video signal. The video signal 1-28 expanded by the decoder 1-27 is output to the monitor 1-31, and displayed as a camera video.

  There is an operator console 1-32 near the monitor 1-31, and an image to be viewed can be selected from a plurality of camera images. For example, a camera video is selected by assigning a number so as not to overlap each camera and pressing a button corresponding to the number. Alternatively, the camera image may be switched in order by a lever or button provided on the console 1-32. If the console 1-32 is a touch panel, it can be incorporated into the monitor 1-31, and the console 1-32 functions by touching the screen of the monitor 1-31 with a finger or a pen. The monitor 1-31 can also be used as a computer monitor, and the computer can be used as the console 1-32 by superimposing the camera image on the computer screen.

  Information on selection of the camera image on the console 1-32 is output to the compressed data selector 1-34 as a camera selection signal 1-33. For example, if an image of the camera 1-1 is selected on the console 1-32, a camera selection signal 1-33 indicating the camera 1-1 is output to the compressed data selector 1-34.

  The compressed data selector 1-34 selects compressed data to be decompressed from the information of the input compressed data selection signal 1-35. In this example, the compressed data corresponding to the camera 1-1 is compressed data 1-4, the camera 1-9 corresponds to the compressed data 1-12, and the camera 2-3 corresponds to the compressed data 2-6.

With the operation as described above, compressed data corresponding to one camera is selected from a plurality of cameras using the console 1-32, and a camera image is displayed on the monitor 1-31.
Next, in the above configuration, a screen display example of the monitor 1-31 is shown in FIG.

  In this example, the monitor 1-31 is a computer screen, and the camera video is superimposed and projected on a part of the computer screen. In this case, the console 1-32 is an input device of the computer, for example, a keyboard or a mouse connected to the computer.

  FIG. 3 is an example of a monitor display image 3-6 displayed on the monitor 1-31, and on this screen, the camera image 3-1, the selection button 3-2 of the camera 1-1, and the camera 1-9 are displayed. A selection button 3-3, a selection button 3-4 of the camera 2-3, and an instruction pointer 3-5 are displayed.

  The camera video 3-1 is a video obtained by compressing the image on the transmission side, transmitting the video to the network 1-25, and performing decompression processing on the reception side decoder 1-27. In this example, since there are three cameras on the transmission side, any one of the three types of camera images is displayed.

  The camera selection button 3-2 is for selecting the camera 1-1. Similarly, the camera selection button 3-3 is for selecting the camera 1-9, and the camera selection button 3-4 is for selecting the camera 2-3. This selection method uses an operation console 1-32, moves an instruction pointer 3-5 that can be freely moved on the screen onto a selection button, and further performs an operation for determination from the operation console 1-32. Select by doing. For example, if a mouse is connected to the console 1-32, by moving the mouse, the instruction pointer 3-5 is moved on the screen, stopped on a predetermined selection button, and the mouse button is pressed. It will be decided.

By such an operation, one of the three cameras connected to the transmission side can be selected and displayed as a camera image 3-1 on the monitor 1-31.
Note that although the case where the input device connected to the console 1-32 is a mouse has been described as an example, any one of the three camera images can be displayed by pressing a predetermined key on the keyboard using a keyboard instead of the mouse. It doesn't matter if you choose.

  In addition, the display position and size of the camera image 3-1, the camera selection button 3-2, the camera selection button 3-3, the camera selection button 3-4, and the instruction pointer 3-5 in the monitor display image 3-6. Does not have to be the same as this figure.

  The camera selection method as described above switches a plurality of camera images connected to the network. However, since the monitor display image 3-6 can display only one camera image, a plurality of cameras are connected to the network. If it is, it is not possible to know what video each camera is currently shooting without actually switching the camera from the console 1-32.

  If three cameras are connected to the network, and the three camera images are simultaneously displayed on the monitor display image 3-6 on the monitor 1-31, the data amount received by the decoder on the receiving side is the network 1 The transmission capacity must be the same as the transmission capacity of −25, and moving image data cannot be transmitted through a transmission path with a small data transmission capacity. In addition, it is difficult for the decoder 1-27 to simultaneously process a plurality of compressed data using such a large transmission capacity in terms of processing speed. When compressing multiple camera images on the transmission side and transmitting them to the network, all the compressed data cannot be processed due to the limited transmission capacity on the reception side. Therefore, the received camera must be switched on the console. The content of the video cannot be confirmed.

  The present invention eliminates these disadvantages, and when a plurality of camera images are compressed on the transmission side and transmitted to the network, all the compressed data cannot be processed due to the limited transmission capacity on the reception side. The purpose is to solve the problem that the contents of the received camera video cannot be confirmed unless it has been switched.

  In order to achieve the above object, the present invention provides a plurality of transmission devices including a camera and an encoder for compressing the camera video, a decoder and a monitor for decompressing compressed data, and a plurality of reception devices including a console. In the compressed image transmission apparatus connected to the network, the reference screen data corresponding to a plurality of camera images is transmitted using a part of the transmission capacity of the network.

  In addition, compressed data that is a high-definition image and reference screen data that has a higher compression rate and a smaller data size than the compressed data are simultaneously output to the network from the encoder on the transmission side.

  Also, a decoder that decompresses predetermined compressed data transmitted over the network and outputs a corresponding video signal to a receiving side, and a plurality of decoders that decompress a plurality of reference screen data and output a plurality of corresponding reference videos And a video synthesizer that synthesizes the expanded video signal and the plurality of expanded reference videos, and outputs and displays the synthesized video signal on a monitor.

The receiving side has means for selecting and selecting one of the plurality of camera videos on the transmitting side from the plurality of reference videos displayed on the monitor on the receiving side.
That is, according to the present invention, high-compression reference screen data is generated by each encoder connected to the network and transmitted to the network. The ratio of the reference screen data to the transmission capacity of the network is very small, and the receiving side can receive all the reference screen data and output it to the monitor. As a result, all camera images can be confirmed on the monitor screen on the receiving side.

  By using the configuration of the present invention described above, it is possible to realize a compressed image transmission apparatus capable of switching camera images while viewing a reference screen on the receiving side.

FIG. 1 is a diagram showing a configuration of a compressed image transmission apparatus in which a plurality of moving image data compression apparatuses and receiving terminals are connected to a network according to the present invention.
On the transmission side, a camera that outputs video data and an encoder that compresses video data are used as a unit, and a plurality of these combinations are connected to the network. In this example, there are two cameras, camera 1-1 and camera 1-9, and these two combinations are connected to the network 1-25, respectively.

  The encoder 1-3 performs image compression processing on the video signal 1-2 output from the camera 1-1. The compressed data 1-4 output from the encoder 1-3 is output to the network 1-25.

  Also, the encoder 1-3 performs an image compression process capable of high compression on the video signal 1-2, and outputs it as reference screen data 1-5. Here, the reference screen data 1-5 is characterized by a high compression rate. Therefore, compression processing is performed after the image data is converted into image data smaller than the image size of the video signal 1-2. Alternatively, high compression is realized by performing compression processing with the frame rate being smaller than that of the video signal 1-2. The image quality may not be a high-definition image such as the compressed data 1-4 but may be a deteriorated image, and a certain degree of image deterioration tolerance allows a higher compression image compression process.

  Similarly, the video signal 1-10 output from the camera 1-9 is subjected to image compression processing by the encoder 1-11 and output to the network 1-25 as compressed data 1-12. In addition, image compression processing capable of high compression is performed on the video signal 1-10, and is output to the network 1-25 as reference screen data 1-13. The above is the configuration on the compressed data transmission side.

  Next, on the receiving side, a combination of a decoder and a monitor that performs decompression processing of the transmitted compressed data is used as one unit, and a plurality of such combinations are connected to the network 1-25. In this example, one combination of the decoder 1-27 and the monitor 1-31 is connected.

  The decoder 1-27 takes one of the two compressed data on the network 1-25 as the compressed data 1-26, and performs image expansion processing. The expanded image data is output to the video signal synthesizer 1-29 as the video signal 1-28.

  The decoder 1-38 takes in the reference screen data 1-5 output to the network 1-25 as reference screen data 1-37, performs image expansion processing, and then outputs the video signal synthesizer 1 as the reference video 1-39. Output to -29.

  The decoder 1-41 takes in the reference screen data 1-13 output to the network 1-25 as reference screen data 1-10, performs image expansion processing, and then performs a video signal combiner 1-42 as a reference video 1-42. To 29.

  The video signal synthesizer 1-29 synthesizes the input video signal 1-28, reference video 1-39, and reference video 1-42 and monitors it as a composite video signal 1-30 which is one piece of image data. Output to 1-31.

  The console 1-32 is installed to send an instruction to the transmission side while viewing the video on the monitor 1-31. The configuration of this console 1-32 is the same as the conventional one. Information when a camera is selected on the console 1-32 is output to the compressed data selector 1-34 as a camera selection signal 1-33.

  The compressed data selector 1-34 determines which camera video data has been selected by the console 1-32 from the contents of the camera selection signal 1-33. Based on the result, compressed data corresponding to the selected camera is selected and output to the decoder 1-27 as a compressed data selection signal 1-35.

Next, the operation of the compressed image transmission apparatus in which a plurality of moving image data compression apparatuses and receiving terminals are connected to a network based on the present invention of FIG.
The video signal 1-2 output from the camera 1-1 is subjected to image compression processing by the encoder 1-3, and is output to the network 1-25 as compressed data 1-4. At the same time, the video signal 1-2 is subjected to compression processing capable of high compression, and is output to the network 1-25 as reference screen data 1-5. The compressed data 1-4 and the reference screen data 1-5 are based on the same video, but their compressed data sizes are greatly different, and the ratio of the reference screen data 1-5 to the compressed data 1-4 is from 1/10 to 100. A fraction.

Similarly, video data 1-10 output from the camera 1-9 is output as compressed data 1-12 and reference screen data 1-13 by the encoder 1-11.
As a result, four moving image compressed data of compressed data 1-4, compressed data 1-12, reference screen data 1-5, and reference screen data 1-13 are input to the network 1-25. The data transmission capacity of the network 1-25 is finite, and it must be controlled so that the total of the four compressed data does not exceed the transmission capacity.

  Here, for example, the compressed data size of the compressed data 1-4 and the compressed data 1-12 is the same value as the compressed data size when the transmission capacity of the conventional network 1-25 is equally divided into one third. Restrict. The compressed data 1-4 and the compressed data 1-12 occupy one third, and the reference screen data 1-5 and the reference screen data 1-13 are transmitted using the remaining one third of the transmission capacity. As described above, since the size of the reference screen data is small from 1/10 to 1/100 compared to the compressed data, for example, if the size ratio is 1/100, 1 is obtained by combining 100 reference screen data. Equal to the size of one piece of compressed data. This means that 100 reference screen data can be transmitted simultaneously when all the reference screen data are combined into one. A detailed description of the division of the transmission capacity will be described later. The above is the operation on the transmission side.

  On the receiving side, the decoder 1-27 connected to the network 1-25 takes in the compressed data 1-4 or the compressed data 1-12 transmitted over the network 1-25, and performs image expansion processing. I do. Which compressed data is taken depends on the compressed data selection signal 1-35. In the image expansion processing, expansion processing for returning the compressed data to the original video signal is performed.

The video signal 1-28 expanded by the decoder 1-27 is output to the video signal synthesizer 1-29.
The decoder 1-38 takes in the reference screen data 1-5 as the reference screen data 1-37 via the network, performs image expansion processing, and outputs it as a reference video signal 1-39 to the video signal synthesizer 1-29.

  Similarly, the decoder 1-41 takes in the reference screen data 1-13 as the reference screen data 1-40 via the network 1-25, performs image expansion processing, and uses the video signal synthesizer 1-42 as the reference video signal 1-42. To 29.

  The video signal synthesizer 1-29 receives three images of the video signal 1-28, the reference video signal 1-39, and the reference video signal 1-42. Each video signal is superposed so that it is displayed at a position that matches the screen layout of the monitor 1-31, and is output to the monitor 1-31 as a composite video signal 1-30 that is a single image. The This screen layout will also be described later.

  The monitor 1-31 displays the composite video signal 1-30 as a camera video. All the reference images are displayed on the screen of the monitor 1-31, and it is possible to grasp what all the cameras are capturing from this image.

  There is an operator console 1-32 near the monitor 1-31, and one camera image is selected based on a plurality of reference images displayed on the screen. Information on the selection of the camera image on the console 1-32 is output to the compressed data selector 1-34 as a camera selection signal 1-33.

  The compressed data selector 1-34 selects compressed data to be decompressed from the information of the input compressed data selection signal 1-35. In this example, the compressed data corresponding to the camera 1-1 is compressed data 1-4, and the camera 1-9 corresponds to compressed data 1-12.

  With the operation as described above, the compressed data corresponding to one camera is selected from a plurality of cameras while viewing the reference video using the console 1-32, and the desired camera video is displayed on the monitor 1-31. indicate.

Next, in the above configuration, a screen display example of the monitor 1-31 based on the present invention is shown in FIG.
In this example, the monitor 1-31 is a computer screen, and the camera video is superimposed and projected on a part of the computer screen. In this case, the console 1-32 is an input device of the computer, for example, a keyboard or a mouse connected to the computer.

  FIG. 4 is an example of a monitor display image 4-5 displayed on the monitor 1-31, and this screen includes a camera image 4-1, reference screens 4-2 and 4-3, and an instruction pointer 4-4. Is displayed.

  The camera video 4-1 is a video obtained by compressing the transmission-side camera video and transmitting it to the network 1-25, and performing decompression processing by the reception-side decoder 1-27. In this example, since there are two cameras on the transmission side, one of two types of camera images is displayed.

  The reference screen 4-2 is for displaying and selecting an image captured by the camera 1-1. Similarly, the reference screen 4-3 is used to display and select an image captured by the camera 1-9. The selection method uses the console 1-32, moves an instruction pointer 4-4 that can be freely moved on the screen onto the reference screen, and further performs a determination operation from the console 1-32. Select by. For example, if a mouse is connected to the console 1-32, the instruction pointer 4-4 is moved on the monitor display image 4-5 by moving the mouse, and is stopped on a predetermined reference screen. Confirm by pressing the button.

  By such an operation, while viewing the video currently captured by the camera based on the reference screen, one of the two connected cameras is selected, and the camera video 4- on the monitor 1-31 is selected. 1 can be displayed.

  Note that the display positions and sizes of the camera video 4-1, reference screen 4-2, reference screen 4-3, and pointing pointer 4-4 in the monitor display image 4-5 are not the same as this figure. However, various layouts are possible.

Next, a network transmission capacity dividing method will be described with reference to FIGS. 5 and 6. FIG.
In a compressed image transmission apparatus in which a plurality of conventional moving image data compression apparatuses and receiving terminals are connected to a network, it is assumed that five cameras are connected on the transmission side.

  In order to transmit video images of five cameras so as not to exceed the transmission capacity of the network, for example, the transmission capacity of the network may be equally divided into 1/5 and allocated to encoders connected to each camera. When the numbers from the compressed data 5-1 to the compressed data 5-5 are sequentially given to the five compressed data output from each encoder, the transmission capacity of the network is equally divided into five as shown in FIG.

On the other hand, a transmission capacity dividing method based on the present invention is shown in FIG.
First, one camera on the transmission side is reduced to four. The transmission capacity of the network is equally divided into 1/5, which is the same as in FIG. Then, since there are four cameras, the transmission capacity equal to one compressed data is not used. All the reference screen data output from the transmission side is assigned to this free transmission capacity.

Since one encoder outputs one compressed data and one reference screen data, if there are four cameras, there are four reference screen data.
Further, as described above, the ratio of the reference screen data to the compressed data is as small as 1/10 to 1/100. Therefore, for example, assuming that the ratio is 1/10, all four reference screen data can be combined. It becomes smaller than the size of one compressed data. Therefore, even if all the reference screen data are combined and allocated to the empty transmission capacity portion, the total of all the transmission data capacity does not exceed the transmission capacity of the network.

  The same applies when the number of cameras on the transmission side increases. If 99 cameras are connected on the transmission side, the ratio of the reference screen data to the compressed data can be reduced to 1/100. Even if all the screen data is combined, it does not exceed the transmission capacity of the network.

  Generally expressing this relationship, if the number of cameras on the transmission side is N, the transmission capacity of compressed data allocated to one encoder is a value obtained by dividing the network transmission capacity by 1 / (N + 1). The ratio of the reference screen data to the compressed data is 1 / (N + 1). When this transmission capacity limitation is satisfied, the entire transmission capacity of the network is used. In practice, this limit may be changed to allow for a vacant network transmission capacity and may be set with a margin.

  As described above, the encoder compression data and reference screen data on the transmission side are output simultaneously, and a camera is selected while viewing the reference screen on the reception side by assigning a part of the network transmission capacity to the transmission of the reference screen data. You will be able to

The block diagram which shows the structure of one Example of the compressed image transmission apparatus with the reference screen of this invention. The block diagram which shows the structure of the conventional compressed image transmission apparatus. The schematic diagram which shows the example of a conventional monitor screen display. The schematic diagram which shows the example of a monitor screen display with the reference screen of this invention. The figure which shows the division | segmentation method of the transmission capacity of the conventional network. The figure which shows the division | segmentation method of the transmission capacity of the network with the reference screen of this invention.

Explanation of symbols

1-1, 1-9: Camera, 1-3, 1-11: Encoder, 1-25: Network, 1-27, 1-38, 1-41: Decoder, 1-29: Video signal synthesizer, 1 -31: Monitor, 1-32: Console, 1-34: Compressed data selector.

Claims (2)

An image transmission method in an image transmission system for transmitting compressed image data and reference screen data from a plurality of image transmission apparatuses via a network,
When the plurality of image transmission apparatuses are N units and the transmission capacity of the network is Q, a transmission capacity of Q / (N + 1) is allocated to each transmission of the compressed image data, and the N number of the transmission apparatuses An image transmission method, wherein a transmission capacity of Q / (N + 1) is allocated for transmission of reference screen data. An image transmission method in an image transmission system for transmitting at least reference image data among compressed image data and reference screen data from a plurality of image transmission apparatuses via a network,
An image transmission method characterized by securing a transmission capacity necessary for transmitting the N pieces of reference screen data when the plurality of image transmission apparatuses are N.

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