JP2003250138A - Video on demand communication system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video on demand (VoD) communication system capable of reducing a required band of a network when using an IP multicast protocol to execute VoD distribution and relieving a load on reception processing and transfer processing. <P>SOLUTION: In dividing contents, a server divides the contents so that a relationship between an n-th division file time and an (n-1)th division file time is expressed in a geometrical progression Sn=α×Sn-1, and a client receives the contents by one multicast group each and uses a band of a multiple of α in comparison with a stream reproduction band to receive and reproduce the contents. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a video on demand (VoD) communication system using an IP multicast protocol. The present invention relates to a division technique of a section division control technique of a content server, a reception technique and a download technique of a client multicast group.

[0002]

2. Description of the Related Art Multicast VoD (V
Ideo on Demand) technology is drawing attention. The multicast VoD technology delivers a content using an IP multicast protocol that reduces the bandwidth of the entire network when a certain content is desired to be provided to a plurality of users who request the content, and realizes video on demand. This is a technology that enables the user to view the content at any time the user wants to watch.

As a conventional VoD service, there is a unicast type delivery system shown in FIG. Content is distributed from the content server to a client, which is a receiving terminal, via a relay router and an edge router. This Figure 1
In the unicast type delivery system shown in Fig. 2, the number of viewing users increases, and the problems of bandwidth usage and server load occur. Therefore, it is difficult to deploy a scalable service when there are many viewing users in a large-scale network. .

In FIG. 1, the content server 1 has a capacity of 6 Mb.
It is assumed that there are 10,000 users (clients 2) who deliver high quality video of ps and watch this content. Content server 1 has 10,000 users
Since unicast distribution is performed for people, a 60 Gbps band must be prepared, and unicast distribution for 10,000 users must be processed by the content server 1. When the number of users who view the content further increases, the content server 1
Since the increased bandwidth must be prepared on the side and the load on the content server 1 also increases,
There is a problem that the number of users cannot be dealt with in order to deliver high quality contents on demand. For these reasons, the VoD service currently deployed on the Internet is of low quality.

On the other hand, the IP multicast type delivery is as shown in FIG. 2, and when delivering under the same conditions as in FIG. 1 (delivering a high quality video of 6 Mbps to 10,000 users),
The content server 1 may have a minimum required bandwidth of 6 Mbps for delivering contents irrespective of the number of users, and
It can be realized by server processing for users. Accordingly, the IP multicast type VoD service is expected as a technology capable of solving the problem of the unicast type service.

In FIGS. 1 and 2, reference numeral 3 indicates a relay router on the Internet, and reference numeral 4 indicates an edge router on the Internet.

The technique shown in FIG. 3 has been proposed as a technique for artificially realizing VoD using the multicast distribution technique shown in FIG. In this case, the network is equipped with a content server 1 that registers the same content in a plurality of multicast group addresses and distributes it with a time shift, and a function of receiving the IP multicast protocol.
(Internet Group Management Protocol below IGMP
And a client 2 that receives the content from the content server 1 by using the IP multicast protocol provided between the content server 1 and the client 2, and the relay that relays the file of the content encoded using the IP multicast protocol. It is composed of a router 3 and an edge router 4.

When the client 2 requests join from the terminal when it wants to view from the terminal, the client 2 receives from the group closest to the viewing start time among the multicast groups distributed from the content server 1 to view. Is started.

In this method, as shown in the time chart on the right side of FIG. 3, the content distribution time difference ΔT changes depending on the number n of a plurality of contents transmitted on the content server 1 side. Since the time difference ΔT becomes smaller, the viewing timing accuracy of the user is improved, but there is also a problem that the bandwidth of the network is increased. For example, if a two-hour program is registered in the 100 multicast group address of the content and distributed at different times, the distribution time difference is 120 minutes / 100 = 1.2 minutes, so the viewing timing accuracy is high and the VoD service is established. On the other hand, the bandwidth of the entire network is required to be 100 times, and the advantage of IP multicast distribution cannot be fully utilized.

As a countermeasure, there is a method proposed by Digital Fountain. This structure is shown in Figures 4 and 5 (http://www.digitalfountain.com/technology/inde
x.htm).

First, as in the case of FIG. 2, the network divides a file such as video content into a plurality of files, performs packet redundancy coding on the plurality of divided files, and registers these coded files in the IP multicast group. , The content server 1 that transfers these groups using the IP multicast protocol and executes the video on demand, and the function of receiving the IP multicast protocol are implemented, and the IP multicast reception protocol IGMP (Internet Group Management Protocol) is used. Provided between the content server 1 and the client 2 and a client (communication terminal) 2 that receives the encoded file from the content server 1 and implements the IP multicast protocol and uses the IP multicast protocol to transmit the encoded file. Relay relay router 3,
It is composed of the edge router 4.

Here, as shown in FIG. 4, the feature of this method is that the content server 1 divides the video content in order from the start point where the viewing of the content starts, and the first divided file time is S1. Minute, the second divided file time is S2 minutes, the third divided file time S3 minute is the sum S1 + S2 of S1 and S2,
The fourth divided file time S4 minutes is the sum S of S2 and S3.
2 + S3, ..., The relationship between the n-th divided file time, the (n-1) th divided file time, and the (n-2) th divided file time is the Fibonacci sequence Sn = Sn-1 +.
It is divided so that it becomes Sn-2 ("Access Multiple Mir
ror Sites in Parallel: Using TornadoCodes to Speed
Up Downloads "SIGCOMM 1998). Also, the content server 1 uses the Luby Transform (" A Digital Fountain
Approach to Reliable Distribution of Bulk Data "In
Encoding is performed using packet redundancy encoding technology such as focom 2001). Each divided file is made redundant according to the packet redundancy rate, and each redundant packet is added with an n-byte message to each packet based on the logical operation XOR so that it can be decoded when received by the client side. To do.

When the client receives the coded file, the client receives the coded files in groups of two in the order in which the content starts to be viewed, and when the reception of one group ends, changes to the next coded file group. ,
Always receive two groups at a time. In this way, the multicast VoD using the section division control technology and the packet redundancy coding technology as shown in FIG. 5 can be realized.

In this method, the number of contents to be transmitted on the contents server side is only the number n of divided files, so that the bandwidth of the entire network can be significantly reduced. On the other hand, since the receiving side (client) receives the multicast group every two groups, the access band of the client is required to be twice as large as that of the conventional one as compared with the unicast VoD system.

[0015]

DISCLOSURE OF THE INVENTION Digital Founta
In the method proposed by in company, the client needs to receive two multicast groups at the same time. At this time, the following problems occur. 1. Since the client has to perform the receiving process of the next coded file group while continuing to receive the other one of the two groups after the reception of one group is completed, a load is imposed on the reception control of the IGMP or the like. . 2. In the case of 1, the client must receive the two groups while synchronizing them.
A burden is placed on the reception control of the MP and the like. 3. The edge router must synchronize the two groups to the client while continuing the transfer of the other group when the transfer of one group of the file transfer of the two groups to the client is completed. It takes a heavy load to control transfer. 4. Since the edge router receives a request to join two multicast groups from one client, a burden is placed on multicast admission control such as IGMP. In the case of the current edge router, the load on the reception control such as IGMP is large, which is a problem. 5. The network must use twice the bandwidth when watching content, because the client is always receiving two multicast groups.

The present invention has been made in such a background, and an object of the present invention is to provide a video-on-demand communication system and method capable of performing one-channel section division control of contents and reducing the load of reception processing and transfer processing. To do. It is another object of the present invention to provide a video-on-demand communication system and method capable of doubling the bandwidth required for distribution on the network.

[0017]

The first aspect of the present invention is to:
Register a file of contents including video divided into multiple files as an IP multicast group, and
A server that transfers by the P multicast protocol,
A video-on-demand communication system including a client that receives the file from the server using an IP multicast protocol.

Here, the feature of the present invention is that the server divides the content in order from the start point where the viewing of the content starts, and divides the n-th divided file time and the (n-1) th divided file time. The divided file time is divided so that the relationship becomes a geometric progression (Sn = α · Sn-1), and when the client receives the file, the client receives one group from the file in the first time zone in order. Each of them, and when the reception of one group is completed, the means for changing to the reception of the next file group is used, and a band of the ratio (α) times of the geometric progression as compared with the stream reproduction band is used for the file. And a means for receiving.

The server is provided with means for packet-redundantly encoding the divided contents and registering them as an encoded file in an IP multicast group, and the encoded file is provided between the server and the client by the IP multicast protocol. It is preferable to provide a relay router for relaying.

A second aspect of the present invention is, in a server,
A file of contents including video is divided into a plurality of pieces, the plurality of divided contents are packet redundant encoded, registered in an IP multicast group, and transferred to a client by an IP multicast protocol, and the client is transferred from the server. It is a video-on-demand communication method for receiving the encoded file by an IP multicast reception protocol.

A feature of the present invention is that the server divides the contents in order from the point where the viewing of the contents starts, and the relation between the n-th divided file time and the (n-1) th divided file time. Is a geometric progression (S
n = α · Sn−1), the client receives the coded files one by one in order from the coded file in the first time zone, and the reception of one group ends. Then, the coded file group is changed to the next coded file to be received, and the coded file is received by using the band of the ratio (α) times of the geometric progression as compared with the stream reproduction band. .

A third aspect of the present invention relates to a server for delivering contents, in which contents including video are divided and registered as packet redundant coded files and transferred to clients using the IP multicast protocol. In the content server, when the content is divided into a plurality of pieces, the content is divided in order from the start point where the viewing of the content starts, and the relationship between the n-th divided file time and the (n-1) th divided file time is a geometric progression ( Sn = α · Sn-1),
The divided file is subjected to packet redundancy coding, and the coded file is registered as an IP multicast group.

A fourth aspect of the present invention relates to a client for requesting and receiving content from a server, wherein the server divides the content including video and the start point from which the content starts to be viewed in order. Then, the file is divided so that the relationship between the n-th divided file time and the (n-1) th divided file time becomes a geometric progression (Sn = α · Sn-1), and the divided file is packet redundant encoded. , A client that receives the content registered with this encoded file as an IP multicast group by the IP multicast reception protocol, and when receiving the file, receives one group at a time from the file in the first time zone, Means for changing to the reception of the next file group when the reception of It characterized in that as compared to the stream regeneration zone and means for receiving use bandwidth ratio (alpha) times of the geometric progression with respect.

A fifth aspect of the present invention is a program which, when installed in an information processing device, causes the information processing device to function as a server according to the third aspect of the present invention and as a client according to the fourth aspect. The program that operates as a server is installed in an information processing device, and the information processing device is divided into contents including video to be registered as a packet redundancy encoded file and transferred to a client using the IP multicast protocol. As a function corresponding to the server, when dividing the content into a plurality of pieces, the content is divided in order from the start point where the viewing of the content is started, and the relationship between the n-th divided file time and the (n-1) th divided file time is shown. It is divided into the geometric progression (Sn = α · Sn-1), and Yl then the packet redundancy coding,
It is characterized in that the function of registering this encoded file as an IP multicast group is realized. Also,
By installing the program operating as the client in the information processing device, the information processing device has a function corresponding to the client of the video-on-demand communication system, so that the content including the video starts at the start point of the content on the server. The file is divided in order from the nth divided file time and n-
The relation of the first divided file time is the geometric progression (Sn = α
-Sn-1) is divided, the divided file is packet redundant encoded, and the encoded file is IP-coded.
When the content registered as a multicast group is received by the IP multicast reception protocol, when receiving the file, one file is received in order from the file in the first time zone, and when the reception of one group ends, the next file is received. The present invention is characterized by realizing a means for changing to group reception and a function for receiving the file by using a band that is a ratio (α) times of the geometric progression as compared with the stream reproduction band.

A sixth aspect of the present invention is a recording medium readable by an information processing device, in which the program of the present invention is recorded. The program of the present invention can be installed in an information processing apparatus using the recording medium of the present invention.
Further, the program of the present invention can be installed in the information processing apparatus, for example, a server from the server via the network.

The present invention first focuses on the file division method in the content server that delivers the content, and the server divides the content including the video in order from the start point where the viewing of the content starts at the time of division. Instead of doing a split based on the Fibonacci sequence of
We propose a method of division based on the geometric progression Sn = α · Sn-1. That is, if the first divided file time is S1, the second divided file time S2 is α times S1.
× S1, the third divided file time S3 is multiplied by α from S2. Α × S2 = α × α × S1, ..., There is a relation between the nth divided file time and the (n-1) th divided file time. It divides so that the geometric progression Sn = α · Sn-1.

When a client (user's communication terminal) receives a coded file, it does not reproduce the contents by simultaneously receiving two conventional multicast groups, but receives the coded files one multicast group at a time. Then, at that time, the content is reproduced by receiving using the band that is α times the stream reproduction band.

According to the present invention, which is configured as described above,
When a client receives a coded file, it is possible to receive one group at a time from the coded file in the first time zone, and even if only one group is received, it can be continuously played at each group switching. To be realized. In addition, it is possible to divide the number of distribution multicast groups.

It will be described that the present invention enables continuous reproduction every time a group is switched.

When the content is divided, the size of the first group at which the viewing of the content starts is a ₁ and the division method is based on the geometric progression Sn = α · Sn-1. Then k
The size of the channel mesh can be expressed as α ^k-1 a ₁ .
Next, regarding the downloading of the partner communication terminal (client), if the client downloads in a band of α times for each group, the time T _Fk required for ending the k-th download is

[Equation 1] Becomes Next, regarding the content reproduction method, assuming that the reproduction is performed after the startup time τ, the k-th start time T _Sk is

[Equation 2] It can be expressed as. For continuous reproduction, the k-th download end time must be earlier than the k-th reproduction start time for any k. T _Sk −T _Fk =
τ-a ₁ / α, where a ₁ / α is the time required to download the file of the first channel, so τ ≧ a ₁ / α. Therefore, at any k, T _Sk ≧ T _Fk , and continuous reproduction is possible with the present invention.

[0031]

DETAILED DESCRIPTION OF THE INVENTION FIG. 2 and FIGS.
An embodiment of the present invention will be described with reference to FIG.

FIG. 2 is a diagram showing a network configuration example of the embodiment of the present invention. FIG. 6 is a diagram showing the detailed operation of the multicast content server according to the embodiment of this invention. FIG. 7 is a diagram showing operations of the content server and the client according to the embodiment of the present invention. FIG. 8 is a diagram showing a packet transfer sequence according to the embodiment of the present invention. FIG. 9 is a diagram showing the detailed operation of the client according to the embodiment of the present invention. Figure 1
0 is a diagram for explaining a series of operations of the embodiment of the present invention.
FIG. 11 is a diagram showing changes in the number of multicast groups when the value of α is changed in the embodiment of the present invention.

The video-on-demand communication network according to the embodiment of the present invention, as shown in FIG.
The content server 1 that provides the D service and the IP multicast reception protocol IGMP for this content
It comprises a client 2 that receives using (Internet Group Management Protocol) and the like, a client 2 that uses the IP multicast protocol, a relay router 3 that relays the content server 1, and an edge router 4.

Content server (multicast VoD
As shown in FIG. 6, the server 1 divides the file of the content including the video into a plurality of files, performs packet redundancy coding on the plurality of divided files, and registers these coded files in the IP multicast group, These groups are transferred using the IP multicast protocol.

Here, as a feature of the present invention, the content server 1 divides the video content in order from the start point where the viewing of the content is started, and the first divided file time is S1. The divided file time S2 of α is multiplied by α × S1, the third divided file time S3 is multiplied by α of S2, α × S2 = α × α × S1, and so on. It divides so that the relation between the file time and the (n-1) th divided file time is the geometric progression Sn = α.Sn-1.

Further, as shown in FIG. 7, the download from the content server 1 to the client 2 receives the encoded files one by one in the order in which the viewing of the content starts, and when the reception of one group ends, the reception ends. The redundant packet is decoded and reproduced. At the same time, the reception of the next encoded file group is changed.

Here, as a feature of the present invention, the download from the content server 1 to the client 2 uses a bandwidth of α times (twice in FIG. 7), which is 1 / α of the normal case. Download at speed.

As shown in FIG. 8, the edge router 4 receives the IP multicast reception protocol IGMP from the client 2 when the client 2 views the content.
Etc., accepts the join request and transfers the group from the content server 1 accordingly. When the reception of one group is completed, the reception of the next coded file group is changed to transfer to the client.

Here, as a feature of the present invention, the edge router 4 transfers from the edge router 4 to the client 2 when transferring the multicast group transferred from the content server 1 to the edge router 4 to the client 2. The bandwidth of is changed to α times (here, twice), and the download is performed at a speed of 1 / α compared to the normal case.

As shown in FIG. 9, the client 2 receives the redundant coded files one group at a time in which the viewing of the content starts, and when the reception of one group ends, the client 2 decodes the received redundant packet, When decoding is completed, playback is performed. When the reception of one group is completed, the next encoded file group is received.

Further explanation will be given by using concrete numerical values in FIG.

It is assumed that a 120-minute program has been uploaded to the content server 1 for distribution and that it will be multicast VoD distributed. In order to deliver the multicast VoD, the file is first divided by the section division control technique. At this time, the geometric progression Sn = α · Sn−1 is used, but here, α = 2 and S0 = 1 (minutes). Since S0 = 1, subsequent file sizes are 2, 4, 8, 16, and 3.
It is divided into a total of 7, which is 2, 64 (minutes).

Next, these are encoded using the packet redundancy coding technique. Then, each encoded file is registered as a multicast group so that it can be distributed by multicast. Here, the relationship between the division time of each encoded file, the destination multicast address, and the group number is shown below. 1ch 1min 224.0.0.11 2ch 2min 224.0.0.12 3ch 4min 224.0.0.13 4ch 8min 224.0.0.14 5ch 16min 224.0.0.15 6ch 32min 224.0.0.16 7ch 64min 224.0.0.17

The client makes a file request when he wants to view this content, but uses the multicast protocol IGMP. First, the multicast address
Join 224.0.0.11 and download.

The content server 1 uses α times (2 in this case).
The file is transferred to the client 2 in the double bandwidth. Two
Since the double bandwidth is used for downloading, the 1-minute file of the multicast address 224.0.0.11 will be downloaded in 0.5 minutes. Content playback will start 0.5 minutes later. At the same time, the client releases (leaves) 224.0.0.11 and joins (j) to the multicast address 224.0.0.12 registered in the next playback file.
oin).

When the reproduction for 1 minute is completed after 1.5 minutes, the content for 2 minutes registered in the next multicast address 224.0.0.12 uses the double bandwidth and the download is completed in 1 minute. The file is reproduced for the next two minutes when the reproduction for one minute is completed. At the same time, the client leaves (224.0.0.12) to the multicast address registered in the next playback file.
Join to 224.0.0.13.

When the reproduction for 2 minutes is completed after 3.5 minutes, the content for 4 minutes registered in the next multicast address 224.0.0.13 is completed in 2 minutes by using the double band, so The file is played for the next 4 minutes when the playback for 1 minute is completed. At the same time, the client leaves (leaves) 224.0.0.13 and joins (joins) multicast address 224.0.0.14 registered in the next playback file.

When the reproduction for 4 minutes is completed after 7.5 minutes, the content for 8 minutes registered to the next multicast address 224.0.0.14 is downloaded in 4 minutes by using the doubled bandwidth. The file is played for the next 8 minutes when the playback for 1 minute is completed. At the same time, the client leaves (leaves) 224.0.0.14 and joins (joins) the multicast address 224.0.0.15 registered in the next playback file.

When reproduction for 8 minutes is completed after 15.5 minutes, 16 registered in the next multicast address 224.0.0.15
Since the download of the content for one minute is completed in eight minutes by using the double band, the file is reproduced for the next 16 minutes when the reproduction for eight minutes is completed. At the same time,
The client releases (leaves) 224.0.0.15 and joins (joins) the multicast address 224.0.0.16 registered in the next playback file.

When the reproduction for 16 minutes is completed after 31.5 minutes,
3 registered at the next multicast address 224.0.0.16
Since the content of 2 minutes is downloaded in 16 minutes by using the double band, the file is reproduced in the next 32 minutes when the reproduction of 16 minutes is completed. At the same time, the client leaves for 224.0.0.16
Then, the multicast address 224.0.0.17 registered in the next playback file is joined.

When the reproduction for 32 minutes is completed after 63.5 minutes,
6 registered at the next multicast address 224.0.0.17
The content of 4 minutes (57 minutes to be precise for a 120-minute program) is downloaded in 32 minutes using the double bandwidth, so when the playback of 32 minutes ends, the next 6
The file is played for 4 minutes. At the same time, the client leaves to 224.0.0.17. With the above, reproduction is realized.

FIG. 11 shows a change in the number of channels on the server side when the required bandwidth α on the user side is changed under the conditions of FIG. Here, a1 = 0.5 minutes. It also shows the case of the method using the Fibonacci sequence (condition: watching a 2-hour program 0.5 minutes later). In the case of the method using the Fibonacci sequence, the client side bandwidth is doubled and the server side bandwidth is required to be 10 ch. From Fig. 11 (10ch, 1.67x)
In the case of (9 ch, 1.98 times), it can be seen that the method of the present invention realizes the multicast VoD with the client side bandwidth being twice or less.

The contents server of the embodiment of the present invention,
The client and the edge router can realize the function by installing a program that realizes the corresponding function in a general-purpose computer device. This program can be installed in a computer device via a recording medium recording the program or a communication line.

[0054]

As described above, according to the present invention, when the client receives the multicast group distributed from the multicast VoD server (content server), it is sufficient to join the multicast group of only one channel. Less affected by the load of IGMP. Also, by changing the value of α in the geometric progression,
When α = 1.67 to 2, the reception bandwidth of the client can be doubled or less, and the required bandwidth of the network can be reduced.

[Brief description of drawings]

FIG. 1 is a diagram showing a unicast type VoD system configuration.

FIG. 2 is a diagram showing the configuration of a multicast VoD system.

FIG. 3 is a diagram showing an example of a multicast VoD system.

FIG. 4 is a diagram showing a detailed operation of a conventional multicast VoD content server.

FIG. 5 is a diagram showing a server client operation of a conventional multicast VoD.

FIG. 6 is a diagram showing a detailed operation of the content server according to the embodiment of the present invention.

FIG. 7 is a diagram showing operations of a server and a client according to the embodiment of the present invention.

FIG. 8 is a diagram showing a packet transfer sequence according to the embodiment of the present invention.

FIG. 9 is a diagram showing the detailed operation of the client according to the embodiment of this invention.

FIG. 10 is a diagram showing a specific operation of the embodiment of the present invention.

FIG. 11 is a diagram showing changes in the number of multicast groups when the value of α is changed in the embodiment of the present invention.

[Explanation of symbols]

1 Content server 2 Client (communication partner terminal) 3 relay router 4 Edge router

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Jun Nishikido             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Senji Kawamura             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F-term (reference) 5C064 BA01 BA07 BB05 BC10 BC11                 5K030 HA08 HB21 HC01 HD03 JA05                       JT04 LD02 LD17

Claims (8)

[Claims] 1. A server that registers a file of content including video divided into a plurality of files as an IP multicast group and transfers the file by the IP multicast protocol, and a client that receives the file from the server by the IP multicast protocol. In the provided video-on-demand communication system, the server divides the content in order from a start point where the viewing of the content starts, and
The client is provided with means for dividing so that the relationship between the n-th divided file time and the (n-1) th divided file time is a geometric progression (Sn = α · Sn-1), and the client receives the file when receiving the file. ,
A means for receiving the files one by one in order from the file in the first time zone, and changing the reception to the next file group when the reception of one group is completed; A video-on-demand communication system comprising means for receiving using a band of a ratio (α) times. 2. The server comprises means for packet-redundantly encoding the divided contents and registering the encoded contents in an IP multicast group as an encoded file, wherein the encoding is performed between the server and the client by an IP multicast protocol. The video-on-demand communication system according to claim 1, further comprising a relay router that relays files. 3. A server divides a file of contents including video into a plurality of files, performs packet redundancy coding on the plurality of divided contents, registers them in an IP multicast group, and sends them to clients via a network by an IP multicast protocol. In the video-on-demand communication method, wherein the client receives the encoded file transferred from the server by an IP multicast reception protocol, wherein the server divides the content in order from a point at which content viewing starts. And the n-th divided file time and the (n-1) th divided file time are divided into a geometric progression (Sn = α · Sn-1), and the client receives the encoded file. Sometimes when the encoding file for the first time zone From the beginning, the group is received one by one, and when the reception of one group is completed, the group is changed to the next coded file group to be received, and the ratio of the geometric progression is compared with the stream reproduction band for the coded file. A video-on-demand communication method, characterized in that reception is performed using a bandwidth twice as large. 4. A server that divides content including video and registers it as a packet redundancy coded file and transfers it to a client using an IP multicast protocol, when viewing the content when dividing the content into a plurality of pieces. Divide in order from the start point,
The file is divided so that the relationship between the n-th divided file time and the (n-1) th divided file time is a geometric progression (Sn = α · Sn-1), and the divided files are packet redundant coded. A server characterized by registering an encrypted file as an IP multicast group. 5. The server sequentially divides the content including video and the start point from which the content starts to be viewed, and the relationship between the nth divided file time and the (n-1) th divided file time is a geometric progression ( Sn = α ・ Sn
-1) is divided, the divided file is packet redundant encoded, and the encoded file is a client that receives the content registered as an IP multicast group by the IP multicast reception protocol, and receives the file. And a means for changing the reception to the next file group when the reception of one group is completed, and comparing the file with the stream reproduction band for the file. And a means for receiving using a band having a ratio (α) times a geometric progression. 6. The server corresponds to a server, which is installed in an information processing device to divide the content including video into a packet redundant coded file and transfer the divided contents to a client using an IP multicast protocol. As a function, when dividing the content into a plurality of pieces, the content is divided in order from the start point where the viewing of the content starts,
The file is divided so that the relationship between the n-th divided file time and the (n-1) th divided file time is a geometric progression (Sn = α · Sn-1), and the divided files are packet redundant coded. A program that realizes a function of registering an encrypted file as an IP multicast group. 7. By installing the information processing device in the server as a function corresponding to the client of the video-on-demand communication system according to claim 1 by installing the information processing device in the server, Divide in order from the start point where viewing starts, and divide so that the relationship between the n-th divided file time and the (n-1) th divided file time becomes a geometric progression (Sn = α · Sn-1). When the divided file is subjected to packet redundancy coding, and the coded file is received by the IP multicast reception protocol with contents registered as an IP multicast group, when the file is received, the file in the first time zone is sequentially ordered. 1
A means for receiving each group, and changing to reception of the next file group when reception of one group is completed, and using a band that is the ratio (α) times of the geometric progression for the file compared to the stream playback band A program that realizes a function of receiving by receiving. 8. A recording medium in which the program according to claim 6 or 7 is recorded and which can be read by the information processing device.