JP3132482B2 - Transfer rate control method and method in image data transfer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a data transfer control system, and more particularly to a transfer control system for compressed image data.

[0002]

2. Description of the Related Art Video-on-demand systems (V)
In a system in which image data is transferred from a video server to a plurality of set-top boxes (Set Top Box, "STB") via a network, such as an video-on-demand system or a "VOD system", a network is used. When the state of congestion occurs, image data is discarded inside the network, and there is a possibility that the image of the STB is disturbed (image stop, mosaic, etc.).

Since it is not economical to secure a band necessary for image transfer to all STBs in a network, it is necessary to estimate the maximum operation rate of the STB and to transfer the image to the STB having the maximum operation rate. Bandwidth is secured on the network.

When a video transfer request is issued from an STB exceeding the maximum operation rate, the video server rejects the video transfer request for an STB exceeding the maximum operation rate.

[0005] For this reason, since exceeding the maximum operation rate is prevented, image data exceeding the bandwidth secured in the network is not transferred, and discarding of image data inside the network due to network congestion can be prevented.

[0006]

However, in the above-mentioned conventional VOD system, there is a problem that the viewer cannot receive the service because the video transfer request from the STB exceeding the maximum operation rate is rejected. .

[0007] Further, since a network is usually used jointly by a plurality of users, even if the operating rate of the STB is kept below the maximum operating rate, the network is secured by using a user other than the VOD system. Congestion may occur in the network due to external factors such as exceeding the allocated bandwidth or deteriorating the processing capacity of the network due to a failure of the network device.

[0008] In this case, in the conventional VOD system, the video server transmits the video data to the STB.
It is possible to eliminate the congestion by interrupting the transfer of video data to some STBs to reduce the load on the network, but the service to the viewer is interrupted. There is a point.

[0009] Therefore, the present invention has been made in view of the above problems, and has as its object the purpose of, for example, when a video transmission request from an STB exceeding the maximum operation rate is generated, or when a network is transmitted due to external factors. It is an object of the present invention to provide an image data transfer system capable of preventing image disturbance and providing services to viewers without interruption even in a congested state.

[0010]

In order to achieve the above object, the present invention provides a method for preparing a plurality of data which are compressed at different compression rates from each other with respect to data transferred via a network. depending on the load conditions, dynamically select the data of the optimum compression ratio from among the plurality of data, the data the selected data
Means for transferring to a destination via the network at a constant transmission rate corresponding to the compression ratio of

[0011]

Embodiments of the present invention will be described below. The present invention is suitable when applied to, for example, a video-on-demand system (Video on Demand system, referred to as a “VOD system”), and converts video data from a video server provided with video image data to, for example, an ATM (Asynchronous). Transfe
r Mode: Asynchronous transfer mode) Set-top box (Set To
When transferring to a terminal such as p Box, "STB", etc., one video is compressed with low transmission rate image data (a high compression rate to reduce the transmission rate, and the image quality is low). A plurality of image data ranging from inferior to high-transmission-rate image data (compressed at a low compression rate so as not to degrade image quality and excellent in image quality) is prepared, and network load conditions such as congestion Means for dynamically selecting image data to be transferred from the plurality of image data in accordance with the detection result of the presence or absence of the image data.

According to a preferred embodiment of the present invention, a plurality of video data (different transmission rates) of one video compressed at different compression rates are stored in a storage means in advance, and the video data is stored in a storage means. Means for monitoring the network traffic to be transferred; and, when detecting a congestion state of the network, switching from video data currently being transferred to video data having a lower compression rate than the video data, and converting the video data having a lower compression rate to the video data. Means for transferring data from the network to a destination node such as an STB at a transmission rate corresponding to a compression ratio.

In the embodiment of the present invention, when the network returns to a normal state without congestion, and when the operation rate of a destination node such as an STB falls below a predetermined threshold, the video data having a low compression rate is used. The video data is switched to the original video data having a higher compression ratio than the video data, and transferred from the network to the equal destination node at a transmission rate corresponding to the compression ratio of the original video data.

Further, in the embodiment of the present invention, when switching from video data currently being transferred to another video data having a compression rate suitable for the network load situation, the video points of both video data coincide. Switching after making adjustments as described above.

According to another embodiment of the present invention, a plurality of video data are stored in different storage means, one of which is a working system and the other is a standby system in which the other storage means is a standby system. Is also good.

[0016]

Embodiments of the present invention will be described below. FIG. 1 shows a video server and an STB according to an embodiment of the present invention.
FIG. 2 is a diagram for describing an example applied to a VOD system in which connections are made by an ATM network.

Referring to FIG. 1, 6 Mbps (megabit / second) video data 1 stored in the hard disk device of the video server 3 is moving image data with a high transmission rate, a low compression rate, and excellent image quality. ing. On the other hand, 3 Mbps video data 2 is moving image data with a low transmission rate, a high compression rate, and poor image quality.

The video server 3 is usually installed in an office that provides a VOD system service, and includes a plurality of STs.
B, when a video transfer request is received from any STB, the video data (6 Mbps video data 1 or 3
Mbps video data 2) is read from the hard disk device and transferred via the ATM network 4 to the STB that sent the request.

STB51 to STB5n are each usually
It is installed in the viewer's residence, transmits a video transfer request to the video server 3 by the viewer's operation, and receives the received moving image data, in this embodiment, 6 Mbps video data 1 or 3 Mbps video data. View video.

Before describing the operation of the embodiment of the present invention, first, general network transfer of moving image data will be described. When transferring moving image data, if raw data (uncompressed data) is transferred to the network as it is, a large transfer band must be secured on the network, which increases communication costs and requires the construction of a large-scale network. Or it is not economical. Therefore, usually, the moving image data is compressed and transferred. In the case of compressing moving image data, it is more economical to compress the moving image data at a high compression rate and lower the transmission rate because the bandwidth secured in the network for transferring the moving image data can be reduced accordingly. However, instead of this, the image quality is degraded as much as the compression rate is increased and the transmission rate is decreased.

In order to simultaneously provide high-quality images to all of the n STBs, 6 Mbps is required.
× n = 6nMbps, ATM network 4 has 6n
It is necessary to secure a bandwidth of Mbps. But always,
Since not all n STB viewers are watching, it is not economical or practical to secure a bandwidth of 6 nMbps in the ATM network 4. For this reason, normally, the operating rate of the STB is assumed, and [maximum operating rate] × [6n
[Mbps] is reserved in the ATM network 4.

In one embodiment of the present invention, referring to FIG. 2, the video server 3 performs load control information (for example, resources) for grasping the load state of the ATM network 4 with the ATM network 4. Management cell), and constantly monitors the load state (traffic) of the ATM network 4. In response to a detection signal from the load monitoring means 31, video data to be transferred to the STB is transmitted at 6 Mbps video. A read control means 32 for controlling switching from data 1 to 3 Mbps video data 2 or vice versa.
6 from the communication control means 33 having the communication interface.
By transmitting the data on the ATM network 4 through a transmission route of Mbps or 3 Mbps, the data is transferred to the destination STB.

When the ATM network 4 is in a normal state (no congestion), the video server 3 reads 6 Mbps video data 1 having excellent image quality from the hard disk device and transfers it to the STB. At this time, the viewer can watch a high-quality video.

In this state, if the operating rate of the STB exceeds the initially estimated maximum operating rate, the video server 3 has a transfer data amount larger than [maximum operating rate] × [6 nMbps]. Since the video data is transmitted to the ATM network 4, the bandwidth exceeds the bandwidth secured in the ATM network 4, and congestion occurs in the ATM network 4.

If the congestion state continues, cell video data is discarded, and the video of the STB may be disturbed.

Therefore, in one embodiment of the present invention, when the network load monitoring means 32 of the video server 3 receives a resource management cell notifying that congestion has occurred from the ATM network 4, the congestion of the ATM network 4 is eliminated. For this purpose, the video data read from the hard disk device is converted from 6 Mps video data 1 to 3 Mbp.
It instructs the read control means 32 to automatically switch to the s-video data 2.

At this time, the 6Mb
The switching is performed after adjusting the switching point from the ps video data 1 to the 3 Mbps video data 2 to be the same video point (same scene) of both video data.

By this switching, the transmission rate per STB is halved from 6 Mbps to 3 Mbps, and the load on the ATM network 4 is also halved.
Congestion can be eliminated.

By this switching of the video data, the image quality which the viewer sees on the STB is inferior to that of 6 Mbps, but the disturbance of the image (the stop of the image due to the discarding of the video data, the occurrence of mosaic, etc.) is prevented You can do it.

When the state of the ATM network 4 returns to a normal state (a state without congestion), the network load monitoring means 32 of the video server 3 detects the elimination of the congestion from the resource management cells transmitted by the ATM network 4. . 6M video data immediately in this state
bps again, the ATM network 4
Video server 3 because congestion may occur in
Waits for the operation rate of the STB to fall below a predetermined threshold level (at least set to a value lower than the maximum operation rate), and then transfers the video data to be transferred from the 3 Mbps video data 2 6 Mbps video data 1.

In one embodiment of the present invention, a plurality of moving image data are prepared for one video, and the plurality of moving image data are stored in separate hard disk devices (35 in FIG. 2).
-1, 35-2). As described above, the hard disk device has a redundant configuration, and for example, a hard disk device that stores 3 Mbps video data can be used as a standby system in the event of a failure, and the reliability of the video server can be improved.

[0032]

As described above, according to the present invention,
The following effects are obtained.

The first effect of the present invention is to prevent image disturbance even when a video transmission request from an STB exceeding the maximum operation rate occurs or when the network is congested due to an external factor. That is, it is possible to provide the service to the viewer without interruption.

The reason for this is that, in the present invention, a plurality of pieces of moving image data from moving image data having a low transmission rate to moving image data having a high transmission rate are prepared for one video, and the load on the network is reduced. This is because moving image data to be transferred is dynamically selected from the plurality of moving image data according to (presence or absence of congestion).

A second effect of the present invention is that a plurality of moving image data are prepared for one video, and the plurality of moving image data are stored in separate storage means. This means that the means can have a redundant configuration and can be used as a standby system in the event of a failure, and the reliability of the video server can be improved.

[Brief description of the drawings]

FIG. 1 is a diagram showing an overall configuration of a system according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a video server according to an embodiment of the present invention.

[Explanation of symbols]

 1 6 Mbps video data 2 3 Mbps video data 3 Video server 31 Network load monitoring means 32 Read control means 33 Communication control means 4 ATM network 51 to 5n STB

Claims (6)

(57) [Claims] 1. A plurality of data obtained by compressing one transfer target data at compression rates different from each other is stored in advance.
Storage means that includes means for monitoring the load status of the network to which the data is transferred, according to the load condition of the network, dynamically select the data of the optimum compression ratio from among the plurality of data, Means for reading from the selected storage means, and transferring the read data to a destination via the network at a transmission rate corresponding to the compression rate, wherein the plurality of data are respectively stored in different storage means. Stored
A data transfer control system wherein one of the storage means is a working system and the other storage means constitutes a standby system and constitutes a redundant system. 2. Different compression for one video
Multiple video data compressed byStore in advanceMemory
meansWhenThe load status of the network to which the video data is transferred
Means for monitoring, and the plurality of videos according to a load status of the network.
Dynamically optimizes video data from video data
To read from the storage unit and correspond to the compression ratio.
Destination network from the network at a fixed transmission rate
Means to transfer toWith The plurality of data are stored in different storage units, respectively.
One of the storage means is the active system and the other is the standby system
Image data characterized by comprising a redundant system
Data transfer device. 3. Different compression for one video
Multiple video data compressed byStore in advanceMemory
meansWhenLoad status of the network to which the video data is transferred
Means for monitoring the video currently being transferred, depending on the status of the network.
From the data, compression suitable for the network load situation
Switch to another video data of different rate and read from the storage means.
At a constant transmission rate corresponding to the compression ratio.
Means to transfer from network to destination nodeWith The plurality of data are stored in different storage units, respectively.
One of the storage means Is the active system and the other storage means is the standby system
Image data characterized by comprising a redundant system
Data transfer device. 4. Different compression for one video
Multiple video data compressed byStore in advanceMemory
meansWhenThe traffic of the network to which the video data is transferred.
Means for monitoring a network which is currently being transferred when detecting the network congestion state.
Transmission rate is lower than that of video data,
Switch to video data with high compression ratio
At the transmission rate corresponding to the compression rate.
To transfer to the destination nodeWith The plurality of data are stored in different storage units, respectively.
One of the storage means is the active system and the other is the standby system
Image data characterized by comprising a redundant system
Data transfer device. 5. When the network returns to a normal state without congestion, when the operation rate of the destination node falls below a predetermined threshold value, the video data having the higher compression rate is compressed at a higher compression rate than the video data. 5. The image data transfer apparatus according to claim 4, wherein the video data is switched to the original video data having a low transmission rate and a high transmission rate and transferred from the network to the destination node. 6. When switching from the video data currently being transferred to another video data having a compression rate suitable for the network unusable situation, the switching is performed by adjusting the video points of both video data so that they match. The image data transfer device according to any one of claims 2 to 5 , wherein: