JP2003018209A - Contents delivery method and terminal management server device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently utilize network resources and to perform contents delivery of high quality when delivering large-capacity contents like video. SOLUTION: A management server A is accessed from a PC 1 to select a program (ST302). When accepting program selection from the PC 1, the management server A counts the number of participant terminals which request delivery of the same contents as the selected program (ST303). Object ONU number '1' is stored (ST304). Next, the management server A generates an acceptance report message and transmits it to the PC 1 (ST305). Thereafter, the management server A transmits a band change report to an OLT device (ST311). The band change report includes a change object ONU, a change time, and a transmission source IP address. The OLT device receives the band change report and changes the band width in accordance with this report.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a content distribution method and a terminal management server device.

[0002]

2. Description of the Related Art In recent years, ADSL (Asymmetric Digital S
Access lines for realizing broadband networks such as ubscriber lines) and FTTH (Fiber To The Home) have begun to spread widely. Along with this, services for distributing content such as moving images via networks are about to reach full-scale diffusion.

When a moving image is distributed via a network, the content capacity is much larger than that of conventional applications such as Web and mail, and the allowable transmission delay time is small. For these reasons, it is necessary to (1) secure network resources (particularly bandwidth) in advance for content distribution, and (2) efficiently use network resources for efficient distribution.

Regarding the former (1), Japanese Patent Laid-Open No. 10-24
As disclosed in Japanese Unexamined Patent Publication No. 3018, an approach in which a required bandwidth is reserved for each traffic flow (corresponding to one video content here) and the flow is preferentially transmitted, and Japanese Patent Laid-Open No. 11- As disclosed in Japanese Patent No. 298482, there is one that attempts to perform transmission control on a packet-by-packet basis by changing the band with a packet transmission end flag.

Regarding the latter (2), on the other hand, Japanese Patent Publication No. 2946193 proposes a multicast connection route selection method capable of efficiently using network resources and selecting a multicast connection route with a small propagation delay. There is.

By the way, it has been said that the cost of an access line using an optical fiber such as FTTH is high, but the difficulty is being solved by a band sharing system in which the optical access line is shared by a plurality of users. .

FIG. 6 shows the configuration of a conventional band sharing system for an optical access line network. An ONU (Optical Network Unit) 61 in FIG. 6 is an optical access line 6
It is a device that provides two UNIs (User-Network Interfaces). In addition, OSU (Optical Subscriber Service Unit: Optical S
The ubscriber unit) 63 is a device that terminates the optical access line 62 on the station side. An OLT (Optical Line Terminal) 64 is a device that accommodates a plurality of OSUs 63 and connects them to the provider's network 65. An optical splitter (optical branching device) 66 is an optical branching circuit that branches one optical access line 62 into a plurality of lines.

In the conventional band sharing system 60 having such a configuration, the band of the optical access line 62 drawn from the OSU 63 is shared by a plurality of ONUs 61. For example, the bandwidth of the optical access line 62 is 10 Mbp
If there are 32 s and ONUs 61, one ONU
About 320 kbps is secured as the minimum guaranteed bandwidth per 61.

[0009]

However, the band sharing system 60 shown in FIG. 6 has the following problems.

The first problem is that a plurality of users share the band of the optical access line 62, and therefore the minimum guaranteed band per person is not sufficient to receive a moving image.
In the above example, the minimum guaranteed bandwidth per user is about 3
Although it is 20 kbps, it cannot receive high-quality contents (for example, a moving image in the MPEG2 format). In order to secure more than the minimum guaranteed bandwidth per user, it is necessary to increase the bandwidth of the optical access line 62 or reduce the number of people sharing the line.
Incurs high costs.

Secondly, in the band sharing system 60 described above, although the minimum guaranteed band for each user can be secured, the secured bands cannot be used among the users. Therefore, even if there are a plurality of users who download the same content, there is a problem that only the minimum guaranteed bandwidth for one user can be secured in the optical access line 62.

This problem will be described in more detail with reference to FIGS. 7 (a) and 7 (b). As shown in FIG. 7A, when the content is distributed by unicast, among the terminals # 1 to # 32 used by a plurality of users, the terminals # 1 and # 3 of the user who wants to view the same content. , # 4 to # 32
Receive the same packet of video A using their respective minimum guaranteed bandwidths. On the other hand, as shown in FIG. 7B, when the content is distributed by multicast, the packet of video A is received using the minimum guaranteed bandwidth of any one terminal (# 1 in this example). At this time, the minimum guaranteed bandwidth of the other terminals (# 3, # 4 to # 32) is not used. Therefore, the band of the optical access line 62 cannot be used efficiently.

The present invention has been made in view of the above points, and can efficiently use network resources and can deliver contents with higher quality when delivering large-capacity contents such as videos. It is an object to provide a content distribution method and a terminal management server device.

[0014]

According to a content distribution method of the present invention, a content distribution server device for distributing content via a network transmission line and at least a part of the network transmission line to the content distribution server device are shared. And a plurality of terminals to which a part of the network resources provided by the network transmission path is individually allocated as the minimum guaranteed amount that is guaranteed to be used for each, and the network resource for content distribution from the content distribution server device. And a network resource control device that secures a part of the content distribution system, the plurality of terminals collecting content information requesting distribution of content from the content distribution server device; Same content at the same time among terminals Detecting a participating terminal requesting distribution, deciding to allocate at least a part of the minimum guarantee allocated to the participating terminal to a shared resource used for the content distribution, and securing the shared resource To notify the network resource control device to do so.

According to this method, the participating resources requesting the distribution of the same content are detected, and at least a part of the minimum guaranteed portion of the network resources allocated to them is secured for the distribution of the content. By sharing the minimum guaranteed amount of the participating terminals with each other, network resources that can be used for content distribution increase, so that network resources can be efficiently used and high-quality program distribution becomes possible.

Further, in the present invention, the plurality of terminals are divided into two or more groups, and each of the groups individually collects content information and detects the participating terminals, and
The detection results of the participating terminals in the group are summarized into 1
The shared resource can be determined from the above-mentioned detection results put together.

According to this method, the plurality of terminals are divided into two or more groups to reduce the management load, and the detection results of the participating terminals in each group are combined into one, and the contents are distributed based on this. Since the network resources to be reserved for this purpose are determined, it is possible to detect the participating terminals from more terminals and share the minimum guaranteed amount held by these terminals.

Further, according to the present invention, it is possible to notify the content distribution server device of shared resources available for content distribution and receive the response from the content distribution server device.

With this method, network resources can be secured for content distribution end-to-end.
Network resources can be used more efficiently, and higher quality content distribution becomes possible.

Further, in the present invention, it is possible to cause the content distribution server device to distribute the content with the highest quality that can be distributed within the range of the notified shared resource.

According to this method, even if there is a plurality of participating terminals and it is not possible to secure the network resource suitable for delivering the highest quality content, the highest quality is ensured within the range of the secured network resource. Good content delivery is guaranteed.

In the present invention, the step of calculating the total of the minimum guarantees allocated to the participating terminals, and if the total is less than the network resources necessary for content distribution, other than the participating terminals Urging the terminal to request the content distribution.

According to this method, if the minimum guaranteed amount of the participating terminals is less than the network resources necessary for content distribution, the non-participating terminals are prompted to participate.
The possibility of increasing the network resources available for content distribution can be positively increased.

Further, in the present invention, if the total minimum guaranteed amount of the participating terminals exceeds the network resource amount necessary for content distribution, the excess amount is additionally allocated to the non-participating terminals. And a step of notifying the resource control device.

According to this method, the step of calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resource required for content distribution, this excess is added to the non-participating terminals. Since it is additionally allocated to, network resources can be used more efficiently.

Further, the present invention further comprises the steps of temporarily storing the content distributed from the content distribution server device, and transmitting the stored content in response to a request from the terminal. good.

Since the content is cached by this method, a fine service such as shifting the time when the non-participating terminal receives the content or suspending the content reception can be realized.

Further, in the present invention, the method further comprises the steps of negotiating an encryption key with a content distribution server device to acquire the encryption key, and notifying the participating terminal of the acquired encryption key. You may.

According to this method, the encryption key is selectively notified to the participating terminals, so that the encryption key can be efficiently distributed only to the terminal that has requested the content distribution.

The terminal management server device of the present invention shares at least a part of the network transmission line up to the content distribution server device with the content delivery server device for delivering contents through the network transmission line, and the network transmission. A plurality of terminals to which a part of the network resources provided by the route is individually allocated as the minimum guaranteed amount to be guaranteed for each use, and a part of the network resources is secured for content distribution from the content distribution server device. A network resource control device,
A terminal management server device provided in a content distribution system comprising: managing a plurality of terminals, wherein the plurality of terminals collects content information requesting the content distribution server device to distribute a content. Means, and a detection means for detecting a participating terminal requesting distribution of the same content at the same time among the plurality of terminals,
Determining means for deciding to allocate at least a part of the minimum guarantee allocated to the participating terminal to a shared resource used for distributing the content, and notifying the network resource control device to secure the shared resource. And a notification means.

With this configuration, the network resource control device detects the participating terminals requesting the delivery of the same content and secures at least a part of the minimum guaranteed portion of the network resources allocated to them for the delivery of the content. By sharing the minimum guaranteed amount of the participating terminals with each other, network resources that can be used for content distribution increase, so that network resources can be efficiently used and high-quality program distribution becomes possible.

Further, in the present invention, one of a plurality of terminal management server devices that manages a plurality of terminals by dividing them into two or more groups, collects content information separately for each group, and detects participating terminals. Further, it further comprises a receiving means for receiving from the other terminal management server device the detection result of the participating terminal in the group managed by the terminal management server device, and the deciding means is configured such that the detection result and the receiving means in the group managed by itself are The shared resource can be determined from both of the detection results received in the group managed by the other terminal management server.

With this configuration, a plurality of terminals are divided into two or more groups and each terminal management server device is provided to reduce the management load of each device, and in a group managed by another terminal management server device. It receives the detection result of the participating terminal and determines the shared resource from both the detection result of the group managed by itself and the detection result of the group managed by another terminal management server, so participation from more terminals It becomes possible to detect terminals and share the minimum guaranteed amount held by them.

The present invention further comprises another notifying means for notifying the content distribution server device of the shared resources available for content distribution, and a response receiving means for receiving the response from the content distribution server device. You may.

With this configuration, network resources can be secured for content distribution end-to-end.
Network resources can be used more efficiently, and higher quality content distribution becomes possible.

In the present invention, the other notifying means are:
It is possible to notify the content distribution server device of the shared resource and cause the content distribution server device to distribute the content with the highest quality that can be distributed within the range of the shared resource.

With this configuration, even if there is a plurality of participating terminals and the network resource suitable for delivering the highest quality content cannot be secured, the highest quality is ensured within the secured network resource. Good content delivery is guaranteed.

In the present invention, the calculating means for calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total is less than the network resources necessary for content distribution, the participating terminals A reminder means for urging the terminal other than the terminal to request the content distribution may be further provided.

With this configuration, if the total of the minimum guaranteed amount of the participating terminals is less than the network resources required for content distribution, the non-participating terminals are prompted to participate,
The possibility of increasing the network resources available for content distribution can be positively increased.

Further, in the present invention, a calculating means for calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resource amount necessary for the content distribution, this excess amount is calculated. An excess amount notifying unit for notifying the network resource control device to additionally allocate to a terminal other than the participating terminal may be further provided.

With this configuration, the step of calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resource required for content distribution, this excess is added to the non-participating terminals. Since it is additionally allocated to, network resources can be used more efficiently.

Further, according to the present invention, there is further provided storage means for temporarily storing the content delivered from the content delivery server device, and content transmitting means for transmitting the stored content in response to a request from a terminal. You may.

With this configuration, since the content is cached, it is possible to realize a fine service such as shifting the time when the non-participating terminal receives the content or suspending the content reception.

Further, in the present invention, encryption key acquisition means for negotiating an encryption key with the content distribution server device to acquire the encryption key, and encryption key notification for notifying the participating terminals of the acquired encryption key. And means may be further provided.

With this configuration, since the encryption key is selectively notified to the participating terminals, it is possible to efficiently distribute the encryption key only to the terminal that has requested the content distribution.

A terminal management server program of the present invention makes a computer share at least a part of the network transmission path up to the content distribution server apparatus with a content distribution server apparatus that distributes contents through the network transmission path, and A plurality of terminals to which a part of the network resources provided by the network transmission path is individually allocated as the minimum guaranteed amount, and one of the network resources is used for content distribution from the content distribution server device. A network resource control device that secures a section, and is a program that is provided in a content distribution system and that functions as a terminal management server device that manages the plurality of terminals, wherein the computer causes the plurality of terminals to perform the content processing. For distribution server device A collection means for collecting content information requesting distribution of content, a detection means for detecting a participating terminal requesting distribution of the same content at the same time among the plurality of terminals, and the minimum guarantee assigned to the participating terminal. And a notifying means for notifying the network resource control device so as to secure the shared resource. .

With this program, the computer
It detects the participating terminals requesting the distribution of the same content, notifies the network resource control device to secure at least a part of the minimum guaranteed amount of network resources allocated to them for the distribution of the content, and Sharing the minimum guarantee increases the network resources that can be used for content distribution, so that network resources can be efficiently used and high-quality program distribution can be performed.

In the present invention, the computer is
A program for managing a plurality of terminals by dividing them into two or more groups, individually collecting content information for each group, and causing the computer to function as one of a plurality of terminal management server devices for detecting participating terminals. A receiving means for receiving the detection result of the participating terminal in the group managed by the other terminal management server device, and the determining means receives the detection result and the receiving means in the group managed by itself. The shared resource can be determined from both of the detection results received by the other terminal management server in the group managed by the other terminal management server.

This program divides a plurality of terminals into two or more groups to reduce the management burden on the computer and receive the detection result of the participating terminals in the group managed by the other terminal management server device, The shared resource is determined from both the detection result of the group managed by itself and the detection result of the group managed by another terminal management server, so the participating terminals are detected from more terminals and are held by these. It becomes possible to share the minimum guarantee.

In the present invention, the computer is
Other notification means for notifying the content distribution server device of shared resources available for content distribution and response receiving means for receiving the response from the content distribution server device may be further functioned.

With this program, network resources can be secured for content distribution end-to-end, so that network resources can be used more efficiently and higher quality content distribution becomes possible.

In the present invention, the other notifying means are:
It is possible to notify the content distribution server device of the shared resource and cause the content distribution server device to distribute the content with the highest quality that can be distributed within the range of the shared resource.

Even if a plurality of participating terminals cannot secure the network resources suitable for delivering the highest quality content by this program,
The highest quality content delivery is guaranteed within the range of secured network resources.

In the present invention, the computer is
Calculation means for calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total is less than the network resources necessary for content distribution, request the content distribution to terminals other than the participating terminals. It may be used as a reminder means to urge the user to further function.

According to this program, if the total of the minimum guaranteed amount of the participating terminals is less than the network resources required for the content distribution, the non-participating terminals are prompted to participate, so that the network resources available for the content distribution are available. The possibility of increasing can be positively increased.

In the present invention, the computer is
Calculation means for calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resource required for content distribution, this excess is added to terminals other than the participating terminals. The excess resource notifying means for notifying the network resource control device to be allocated may further function.

According to this program, the step of calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resources necessary for content distribution, this excess is added to the non-participating terminals. Since it is additionally allocated to, network resources can be used more efficiently.

In the present invention, the computer is
The storage means for temporarily storing the content distributed from the content distribution server device and the content transmitting means for transmitting the stored content in response to a request from the terminal may further function.

Since the content is cached by this program, the time when the non-participating terminal receives the content is shifted, the content reception is temporarily stopped, etc.
A fine-tuned service can be realized.

Further, in the present invention, an encryption key acquisition means for negotiating an encryption key with the content distribution server device to acquire the encryption key, and an encryption key notification for notifying the participating terminal of the acquired encryption key. The means may be further functioned.

Since this program selectively notifies the participating terminals of the encryption key, it becomes possible to efficiently distribute the encryption key only to the terminal that has requested the content distribution.

The present invention includes a computer-readable storage medium storing the above-mentioned terminal management server program.

[0063]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments 1 and 2 of the present invention will be described below.
Will be described in detail with reference to the drawings.

(Embodiment 1) FIG. 1 is a schematic diagram showing a content distribution system according to Embodiment 1 of the present invention. In FIG. 1, the content distribution server device 1 is connected to an Internet backbone network 2 provided by a provider. An OLT device 3 is connected to the Internet backbone network 2. The OLT device 3 includes a plurality of OSUs 4. One end of the optical access line 5 is connected to each OSU 4. An optical splitter 6 is provided at the other end of the optical access line 5. This optical splitter 6
Divides one optical access line 5 into a plurality of user lines 7. Each user line 7 is connected to a plurality of PC1 to PC32 via a plurality of ONU1 to 32.

Further, the optical splitter 6 includes PCs 1 to P
Two management servers A8 and B9 that manage C32 and ONUs 1 to 32 are connected. One management server A8
Is PC1 to PC16 and ONU1 to 16 connected to it
The other management server B9 manages PCs 17 to 32.
And the ONUs 17-32 to which it connects.

In the present embodiment, the total bandwidth of the optical access section of each ONU-optical splitter-OLT is 10 Mbps.
Assuming that 32 ONUs 1 to 32 share this, the minimum guaranteed bandwidth per one ONU is about 320 kbps.

FIG. 2 is a block diagram showing the management server according to the first embodiment. In the management servers A8 and B9, the management server main unit 11 mainly executes various functions of the management server function. The database (E
The bandwidth required for video distribution is calculated with reference to PG information and terminal group information). Further, by utilizing the lower level network function, the content distribution server device 1, the OLT device 3,
Messages are exchanged with the PCs 1 to 32, the management servers A8 and B9, and other management servers.

The Web server function unit 12 is composed of PCs 1 to 32.
In addition to providing EPG information on a Web basis, the information regarding video viewing input from the Web browser of the PCs 1 to 32 is received and stored in the terminal group information.

The video information processing unit 13 stores the video information received from the content distribution server device 1 via the network function in the video storage unit for use as a cache.

The encryption unit 14 exchanges the encryption key with the content distribution server device 1, the PCs 1 to 32 or another management server. For example, SSL (Secure Socket Layer)
A general encryption protocol such as can be used.

Further, the management servers A8 and B9 use the TCP layers 15 and U to execute communication on the network.
DP layer 16, IP layer 17, and Ethernet (R)
The functional unit 18 is provided.

The management servers A8 and B9 have the following databases. The EPG information 19 is the EPG (Electronic Pro) received from the content distribution server device 1.
gramGuide: Electronic program guide) information (specifically, program type,
Start time and time, transmission rate, transmission format,
Store price information). The data is stored in a memory such as a DRAM and also stored in a hard disk drive (HDD) for backup and updated at any time.

The terminal group information 20 is the management server A.
8, the information of the terminal group (PC1 to PC32) managed by B9 is stored. Specifically, the terminal group information 20 indicates that each PC 1
~ Network resources (bandwidth) allocated to PC 32
Information, information on programs scheduled to be viewed, and the like. The data is stored in the memory and also stored in the HDD for backup and updated as needed. Furthermore, the video storage unit 21 is
This is an area reserved on the DD for storing one video information.

FIG. 3 is a sequence diagram showing data exchange in the content distribution system according to the first embodiment.

In FIG. 3, the management server A8 has PC1 to PC1.
The case where the program reception from the PC 16 is accepted is illustrated.

The management server A8 previously receives the EPG data distributed by the content distribution server device 1 (ST3).
01). One piece of EPG data is composed of a program name, distribution time, distribution rate, distribution address, and the like. An example is shown below.

EPG data <program name = live A: time =
19:00 to 20:00: Transmission rate = 800 kbps: Address at distribution = 224.30.3.5> Next, for example, the management server A8 is accessed from the PC 1 and program selection is performed (ST30.
2). More specifically, the Web browser operating on the PC 1 is the UR of the program selection content of the management server A8.
Access L, download this content data (HTML file, etc.), and display the program selection home page on the display of PC1. This program selection home page is created based on EPG data.

The user who operates the PC 1 selects a program to be viewed from this program selection home page. The program selection can be performed by, for example, clicking a program icon. The Web browser recognizes this program selection and sends a program selection message to the management server A8.

Upon receiving the program selection from the PC 1, the management server A8 counts the number of terminals (hereinafter referred to as participating terminals) requesting the same content distribution as the selected program (hereinafter referred to as participating terminals). (ST30
3). The number of ONU1 connected to PC1 (hereinafter,
“1” is stored as the target ONU number (ST30)
4). Next, the management server A8 creates an acceptance notification message including the multicast IP address (224.30.3.5 in the above example) at the time of program distribution based on the EPG data, and sends it to the PC 1 (ST305). PC1
Can use the multicast IP address included in this acceptance notification message to receive a multicast IP packet at the time of later delivery of program video.

Similarly, when a program for the same program is selected from another PC, for example, the PC 16 (ST30
6), the management server A8 counts the number of participating terminals (ST
307), and the target ONU number “16” is stored (ST308). Next, a reception notification message is created and transmitted to the PC 16 (ST309).

After that, if the condition for ending the program selection acceptance is satisfied, the management servers A8 and B9 determine whether or not the number of participating terminals (2 in this example) of the same program ("Live A") counted up to that point is satisfied. A bandwidth that can be allocated to the content distribution of the program (hereinafter referred to as an allocatable bandwidth) is calculated (S
T310). Specifically, it is calculated by the following equation (1).

Allocatable Bandwidth (kbps) = (Minimum Guaranteed Bandwidth of Each PC1 to PC32) × Number of Participating Terminals (1) As described above, in the present embodiment, each of PC1 to PC32 has 320 kbps. Since the minimum guaranteed bandwidth is allocated and the number of participating terminals is 2 in this example, the allocatable bandwidth is 640 kbps.

Next, the management server A8 transmits a band change notification to the OLT device 3 (ST311). The band change notification includes the ONU to be changed, the change time, and the source IP address. The band change notification is as follows, for example.

<Change target ONU = 1,16: Time = 19: 00 to 2
0:00: Source IP = xxx.xx.xx (IP address of content distribution server device 1)> The OLT device 3 receives the band change notification, and changes the band width accordingly. That is, the OLT device 3 responds to the IP packet transmitted from the designated source IP (IP address of the content distribution server device 1) at the time (19:00 to 20:00) designated by the band change notification. , Specified ONU
The bandwidth originally allocated to (ONU 61, xx) is secured. This allows the same program (“Live A”)
The minimum guaranteed bandwidth in the downlink direction from the OLT device 3 to the PCs 1 and 16 for the content download is changed to 640 kbps, which is the sum of the minimum guaranteed bandwidths originally originally assigned to the two ONUs 1 and 16.

The management server A8 also transmits a video distribution request message to the content distribution server device 1 (ST312). In this video distribution request message,
Allocatable bandwidth calculated in ST310 (64 in this example)
0 kbps) is included. Upon receiving the video distribution request message, the content distribution server device 1 transmits a video distribution response message to the management server A8 (S
T313). This video distribution response message contains the maximum transmittable rate and the encryption key for restoring the encrypted content. The maximum transmittable rate refers to the maximum transmittable rate from the content distribution server device 1 (for example, 600 kbps).

The management server A8 uses the SSL for the PC1 and the PC16 which watch the same program ("live A").
A session capable of encrypted communication such as (Secure Sockets Layer) is established, and the encryption key passed from the content distribution server device 1 is notified on the session (ST31).
4, ST315).

By the exchange up to this point, the PC 1 and the PC 16 are ready to receive the program. Therefore, at the distribution start time (19:00), the content distribution server device 1 transmits the video data to the multicast IP address. (ST316). PC1 and PC16 are
The program is viewed by receiving the video data and decoding the code (ST317, ST318).

On the other hand, the management servers A8 and B9 also serve as cache servers. That is, the management server A
8 stores the received content in the HDD (S
T319). Then, for example, when the PC 2 tries to view the program after the start of distribution (ST320, ST321)
To the encryption key from the management server A8 (ST32
2) The video data stored in the HDD is delivered to the PC 2 from the beginning (ST323).

As described above, according to the content distribution system of the first embodiment, the management servers A8 and B9 are
The OLT device 3 detects PCs that are going to watch the same program and secures all the minimum guaranteed bandwidths allocated to these PCs for the video data distribution of the program from the content distribution server device 1. To instruct. As a result, as the number of participating terminals increases, the band that can be used for program distribution increases, so that the band of the optical access line 5 can be used efficiently and high-quality program distribution becomes possible. At this time, since the minimum guaranteed bandwidth assigned to terminals not participating in program viewing is not used,
It is possible to maintain fairness with respect to terminals that do not participate in viewing programs.

The management servers A8 and B9 also calculate the allocatable bandwidth allocated to the program distribution based on the number of participating terminals and the minimum guaranteed bandwidth of each terminal, and notify the OLT device 3 of a bandwidth change notification (ST311). Separately, this is included in the video distribution request and transmitted to the content distribution server device 1 (ST312). On the other hand, the content distribution server device 1 transmits a response message including the maximum transmittable rate (ST313). As a result, a band for content distribution can be secured end-to-end, so that the band can be used more effectively and higher quality program distribution can be achieved.

In the first embodiment, the management server A8,
It has been described that B9 notifies the content distribution server device 1 of the allocatable bandwidth, and the content distribution server device 1 responds to this with the maximum transmittable rate. It is possible to realize more efficient content distribution by using this negotiation. That is, the content distribution server device 1 determines that the highest quality video data (800 kb
Not only those encoded at a ps rate, but also some quality video data at a reduced rate (for example, 128 for a user placed in a slow network environment).
kbps, 256 kbps and 600 kbps etc.)
Is held in advance. Then, when the allocatable band is designated by the management servers A8 and B9, the content distribution server device 1 selects and distributes the highest quality video data within a range that does not exceed the band. As a result, even if there is a plurality of participating terminals and a band (800 kbp) suitable for distribution of the highest quality video data cannot be secured, the highest quality content distribution is guaranteed in the secured band.

Further, since the management servers A8 and B9 also have the cache server function, it is possible to shift the time at which some terminals receive the content as described above, and to suspend the content reception. A fine-tuned service can be realized.

The management servers A8 and B9 also negotiate the encryption key with the content distribution server device 1 (ST
(312, ST313), the acquired encryption key is selectively notified to the terminal (ST314, ST315), so that the encryption key can be efficiently distributed only to the terminal that desires to watch the program. Security can be improved.

(Embodiment 2) Next, a case will be described in which, when some terminals first participate in viewing a program, the management server invites other terminals to participate. 4 and 5 are sequence diagrams showing data exchange in the content distribution system according to the second embodiment of the present invention.

The management servers A8 and B9 receive EPG data distribution from the content distribution server device 1 in advance (S
T401, ST402). The contents of the EPG data are as follows. EPG data <Program name = Drama A: Time = 21:00 to 22: 0
0: Transmission rate = 800kbps: Address at delivery = 224.50.2.8
> The PC1 and PC17 who are going to view the program access the management servers A8 and B9 in charge thereof to select the program (ST403, ST404) and receive the acceptance notifications (ST405, ST406). These acceptance notifications include the multicast IP address (224.50.2.8) at the time of program distribution.

If the predetermined condition is satisfied, the management server A8 sends a participant inquiry to the management server B9 (ST407). In response to this participant inquiry, the management server B9 transmits a response message notifying the number of participating terminals and the target ONU number of the program "drama A" at that time to the management server A8 (ST408).

After receiving the response message, the management server A8 sums up the number of terminals participating in the management server A8 and the number of terminals notified by the management server B9 to watch the program "Drama A" at the present moment. The total number of participating terminals that participated is calculated (ST409). Then, the allocatable bandwidth of the program is calculated from the total number of participating terminals (ST410). In this example, since the total number of participating terminals is “2”, the allocatable bandwidth is 640 kbp as in the following expression (2).

320 kbps × 2 = 640 kbps (2) The management server A8 has an excess or deficiency of bandwidth based on the allocatable bandwidth (680 kbps) calculated in ST410 and the transmission rate (800 kbps) in the EPG data. Is determined (ST411). In this example, since the band (800 kbps) necessary for receiving the program “Drama A” cannot be secured as it is, the management server A8 determines to solicit participation.

The management server A8 transmits a participation invitation notification to the PCs 2 to 16 which are not subordinate to the management server A8 according to the determination in ST411 (ST412). Also, the management server A8
Sends a solicitation to join to the management server B9 (ST413), and the non-participating PC under the management server B9
18 to 32 is sent a participation invitation notification (ST4
14). Here, various means can be considered for the transmission form of the participation invitation notification, for example, by e-mail.

In response to these invitations for participation, the PC 16
And the PC 32 selects a program (ST41
5, ST416). On the other hand, the management servers A8 and B
9 performs acceptance notification (ST417, ST418).

If the predetermined condition is satisfied, the participant inquiry (ST419), the response (ST420), the total number of participating terminals (ST421), and the allocatable bandwidth (ST4) are calculated again.
22) and determination of band excess / deficiency (ST423) are sequentially performed.

As a result, the total number of participating terminals of the program "Drama A" becomes 4, and the allocatable bandwidth is 1,280 kbps.
The bandwidth exceeds the required bandwidth (800 kbps).

Therefore, the management server A8 calculates the surplus bandwidth (ST424). In this example, it is sufficient to secure a band for 3 terminals, that is, 320 kbps x 3 = 960 kbps, so the minimum guaranteed bandwidth 3 for the remaining 1 terminal is 3.
20 kbps is the surplus bandwidth.

Next, the management server A8 transmits a surplus bandwidth notification to the non-participating PC 2 and the like under the control and the non-participating PC via the management server B9 (ST425, ST42).
6) Notify that the current bandwidth of 320 kbps is left over.

On the other hand, the PC 2 which has not yet participated in watching the "drama A" notifies the management server A8 that the surplus bandwidth is used (ST427).

When the surplus bandwidth (one terminal) has participated, the management server A8 transmits a bandwidth change notification to the OLT device 3 (ST428, ST429).

The band change notification is, for example, as follows.

<Change target ONU = 1,16,17: Time = 21: 00
~ 22: 00: Source IP = xxx.xx.xx (IP address of the content distribution server device 1), change target ONU = 2,32:
Time = 21: 00 to 22:00: Source IP address = arbitrary, destination IP address = IP address of PC2> OLT device 3 receives the bandwidth change notification, and changes the bandwidth accordingly. That is, the OLT device 3 specifies the designated source IP (IP of the content distribution server device 1) at the time (21:00 to 22:00) specified in the band change notification.
For the IP packet transmitted from the (address), the bandwidth originally allocated to the designated ONU (ONU 1, 16, 17) is secured. As a result, the minimum guaranteed bandwidth in the downstream direction from the OLT device 3 to the PCs 1, 16 and 17 for content download of the same program (“Drama A”) is originally individually set to the three ONCs 1, 16 and 17. 960k that is the total of the minimum guaranteed bandwidth that has been allocated
is changed to bps.

Further, the OLT device 3 adds 640 kbps to the IP packet transmitted to the IP address of the PC2, which is the minimum guaranteed bandwidth originally allocated to the ONU 32 combined with the minimum guaranteed bandwidth originally allocated to the PC2. Secure. As a result, the PC 2 can secure the minimum guaranteed bandwidth of 640 kps for the download stream from any source addressed to itself.

Thereafter, ST312 to ST312 of the above-described first embodiment.
Similar to ST318, video distribution request (ST429), video distribution response (ST430), encryption key notification (ST431 to ST431 to ST431)
ST435), video distribution (ST436) and program viewing (ST437 to ST439) are sequentially performed.

As described above, according to the second embodiment, the management server A8 responds to the participant inquiry (ST407) by
Number of participating terminals and target ONUs under another management server B9
The number to be acquired is examined together with the number of participating terminals under its control and the target ONU number to determine the bandwidth used for video data. In this way, the management server A8
Acquires the information (the number of participating terminals and the target ONUs) of the participating terminals (the number of participating terminals and the target ONUs) that will try to view the same program in the terminal group managed by the other management server B9. Participating terminals can be detected from among these and the minimum guaranteed bandwidth held by them can be shared.

In this example, the management server A8 mainly controls the content distribution to the terminal group managed by the management server B9 collectively. However, the management server A
8 and B9 independently manage the content distribution to the respective terminal groups managed by them (for example, bandwidth change notification and video distribution request separately), the management server A8 is a participating terminal in the terminal group managed by itself. Information needs to be transmitted to the management server B. As described above, the management servers A8 and B9 can detect the participating terminals from more terminals by exchanging the participating terminal information with each other, and can share the minimum guaranteed bandwidth held by these terminals with each other. Become.

Further, in the second embodiment, the management server A
No. 8 can be used for content distribution because it prompts non-participating terminals to participate when the total minimum guaranteed bandwidth of participating terminals is less than the bandwidth required for content distribution (that is, the allocatable bandwidth is insufficient). It is possible to positively increase the possibility of increasing the available bandwidth.

On the other hand, when the total of the minimum guaranteed bandwidths of the participating terminals is larger than the bandwidth required for content distribution (that is, the allocatable bandwidth becomes surplus), the management server A8 determines that one of the participating terminals does not receive the video data. Bandwidth allocated to the non-participating terminal by using the minimum guaranteed bandwidth allocated to the section and allocating the surplus to the downstream data transmission to the terminal (source is not limited to the content distribution server device 1) Can be increased, so that the band of the optical access line 5 can be used more efficiently.

In the first and second embodiments, the case where the network band is shared by a plurality of terminals to improve the content distribution has been described as an example. However, network resources include maximum delay and delay variation in addition to bandwidth. The maximum delay is an index indicating how much delay occurs until the image distributed from the content distribution server device 1 reaches the terminal, and if there are multiple routes between the content distribution server device terminals, the delay is The smallest path can be selected. Also, what is the delay variation? Even if a series of video data is transmitted from the content distribution server device 1 at equal intervals, the width of the delay generated in the video data in the middle of the network route becomes uneven, and as a result, the video data received by the terminal is evenly spaced. Indicates that it will disappear. The present invention can be applied to a case where these network resources are secured only for the viewing of the video.

The content is not limited to video. For example, it includes music distribution by Internet radio and electronic newspapers / magazines distributed at a predetermined time.

Further, although the case where the band of the optical access line 5 is shared is described in the present embodiment, the ADS is used.
The present invention can be applied to sharing network resources of broadband lines such as L and FWA (fixed wireless access).

As will be apparent to those skilled in the art, the present invention can be implemented using a general commercially available digital computer and microprocessor programmed according to the technique described in the above embodiments. Further, as will be apparent to those skilled in the art, the present invention includes computer programs created by those skilled in the art based on the techniques described in the above embodiments.

Also within the scope of the invention is a computer program product, which is a storage medium containing instructions that can be used to program a computer implementing the invention. This storage medium is a disk such as a floppy (R) disk, an optical disk, a CDROM and a magnetic disk,
The ROM, the RAM, the EPROM, the EEPROM, the magneto-optical card, the memory card, the DVD, and the like, are not particularly limited thereto.

[0120]

As described above, according to the present invention,
From the content distribution requests from multiple terminals to the content distribution server, the participating terminals requesting the distribution of the same content are detected and the minimum guaranteed amount allocated to these is shared, so that large-capacity content distribution such as video In doing so, it is possible to efficiently use network resources and to deliver contents with higher quality.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a content distribution system according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a management server according to the first embodiment.

FIG. 3 is a sequence diagram showing data exchange in the content distribution system according to the first embodiment.

FIG. 4 is a sequence diagram showing data exchange in the content distribution system according to the second embodiment of the present invention.

FIG. 5 is a sequence diagram showing data exchange in the content distribution system according to the second embodiment.

FIG. 6 is a block diagram showing a configuration of a conventional band sharing system for an optical access network.

FIG. 7 is a diagram showing how contents are distributed in a conventional band sharing system for an optical access line network.

[Explanation of symbols]

1 Content distribution server device 2 Internet backbone network 3 OLT device 4 OSU 5 optical access lines 6 Optical splitter 7 user line 8 Management server A 9 Management server B 11 Management server main section 12 Web server function section 13 Video information processing unit 14 Encryption part 15 TCP layer 16 UDP layer 17 IP layer 18 Ethernet (R) Function Unit 19 EPG information 20 Terminal group information 21 video storage

Claims (25)

[Claims] 1. A content distribution server device that distributes content through a network transmission line, and a network resource that shares at least a part of the network transmission line up to the content distribution server device and that is provided by the network transmission line. A plurality of terminals, some of which are individually allocated as minimum guarantees for which each is guaranteed to be used, and a network resource control device that secures a part of the network resources for content distribution from the content distribution server device, A content distribution system including: a step in which the plurality of terminals collect content information requesting the content distribution server device to distribute the content; and a request for distribution of the same content at the same time among the plurality of terminals. To detect the participating terminals to Deciding to allocate at least a part of the minimum guarantee allocated to the participating terminal to a shared resource used for distributing the content, and notifying the network resource control device to secure the shared resource And a content distribution method comprising: 2. A plurality of terminals are divided into two or more groups, and in each of the groups, the content information is separately collected and the participating terminals are detected, and the detection result of the participating terminals in the group is set to 1 The content distribution method according to claim 1, wherein the shared resource is determined from the detection results that are combined into one and are combined into one. 3. The content distribution method according to claim 1, wherein the content distribution server device is notified of shared resources available for content distribution, and the response is received from the content distribution server device. . 4. The content distribution method according to claim 3, wherein the content distribution server device is caused to distribute the content with the highest quality that can be distributed within the range of the notified shared resource. 5. A step of calculating the total of the minimum guarantee amount allocated to the participating terminals, and if the total is less than the network resources necessary for content distribution, the content is distributed to terminals other than the participating terminals. The method according to any one of claims 1 to 4, further comprising a step of urging a request for distribution. 6. A step of calculating the total of the minimum guaranteed amount allocated to the participating terminals, and if the total exceeds the network resource amount necessary for content distribution, the excess amount is added to other than the participating terminals. 6. The content distribution method according to claim 1, further comprising the step of notifying the network resource control device to additionally allocate the terminal. 7. The method further comprising: a step of temporarily storing the content distributed from the content distribution server device, and a step of transmitting the stored content in response to a request from a terminal. The content distribution method according to any one of claims 1 to 6. 8. A step of negotiating an encryption key with a content distribution server device to acquire the encryption key, and a step of notifying the participation terminal of the acquired encryption key.
The content distribution method according to any one of claims 1 to 7, further comprising: 9. A content distribution server device that distributes content via a network transmission path, and a network resource that shares at least a part of the network transmission path up to the content distribution server device and that is provided by the network transmission path. A plurality of terminals, some of which are individually allocated as minimum guarantees for which each is guaranteed to be used, and a network resource control device that secures a part of the network resources for content distribution from the content distribution server device, A terminal management server device provided in a content distribution system comprising: managing a plurality of terminals, wherein the plurality of terminals collect content information requesting distribution of a content from the content distribution server device. Means and the same at the same time among the plurality of terminals Detecting means for detecting a participating terminal requesting distribution of content, determining means for deciding to allocate at least a part of the minimum guarantee allocated to the participating terminal to a shared resource used for distributing the content, A terminal management server device, comprising: a notification unit for notifying the network resource control device so as to secure a shared resource. 10. One of a plurality of terminal management server devices for managing a plurality of terminals by dividing them into two or more groups, collecting content information separately for each group, and detecting participating terminals,
The terminal further includes a receiving unit that receives the detection result of the participating terminal in the group managed by the other terminal management server device, and the determining unit receives the detection result and the receiving unit in the group managed by itself. 10. The terminal management server device according to claim 9, wherein the shared resource is determined from both of the detection results in the group managed by the other terminal management server. 11. The system further comprises: another notifying means for notifying the content distribution server device of the shared resource available for content distribution, and a response receiving means for receiving a response from the content distribution server device. The terminal management server device according to claim 9 or 10. 12. The other notifying means notifies the content distribution server device of the shared resource, and causes the content distribution server device to distribute the content with the highest quality that can be distributed within the range of the shared resource. 11. The terminal management server device according to claim 10. 13. A calculating means for calculating a total of minimum guarantees allocated to participating terminals, and a terminal other than the participating terminals if the total is less than the network resources necessary for content distribution. 13. The terminal management server device according to claim 9, further comprising a urging unit that urges a request for content distribution. 14. A calculating means for calculating a total of minimum guarantees allocated to participating terminals, and if the total exceeds a network resource necessary for content distribution,
14. An excess amount notifying unit for notifying the network resource control device to additionally allocate the excess amount to a terminal other than the participating terminal, further comprising: The terminal management server device described. 15. The storage system further comprises storage means for temporarily storing the content distributed from the content distribution server device, and content transmission means for transmitting the stored content in response to a request from a terminal. The terminal management server device according to any one of claims 9 to 14. 16. An encryption key acquisition means for negotiating an encryption key with a content distribution server device to acquire the encryption key, and an encryption key notification means for notifying the participating terminal of the acquired encryption key. The terminal management server device according to any one of claims 9 to 15, further comprising: 17. A computer shares at least a part of the network transmission path up to the content distribution server apparatus with a content distribution server apparatus that distributes content through the network transmission path, and the network transmission path provides the computer. A plurality of terminals to which a part of the network resource is individually allocated as the minimum guaranteed amount for which each is guaranteed to be used, and a network resource control that secures a part of the network resource for content distribution from the content distribution server device. A program for causing a terminal management server device that manages the plurality of terminals to function as a terminal management server device that is provided in a content distribution system including: Requesting delivery of Collecting means for collecting information, a detecting means for detecting a participating terminal requesting distribution of the same content at the same time among the plurality of terminals, and at least a part of the minimum guarantee portion allocated to the participating terminal. A terminal management server program, which functions as a deciding means for deciding allocation to a shared resource used for content distribution, and a notifying means for notifying the network resource control device to secure the shared resource. . 18. A computer is made to function as one of a plurality of terminal management server devices that manage a plurality of terminals by dividing them into two or more groups, collect content information separately for each group, and detect participating terminals. The program further causes the computer to function as a receiving unit that receives a detection result of the participating terminal in a group managed by the computer from another terminal management server device, and the determining unit is a group managed by itself. 2. The shared resource is determined from both the detection result of 1. and the detection result of the group managed by the other terminal management server received by the receiving unit.
7. The terminal management server program described in 7. 19. The computer further functions as another notifying means for notifying the content distribution server device of a shared resource available for content distribution and a response receiving means for receiving a response from the content distribution server device. The terminal management server program according to claim 17 or 18, characterized in that the program is executed. 20. The other notifying means notifies the content distribution server device of the shared resource, and causes the content distribution server device to distribute the content with the highest quality that can be distributed within the range of the shared resource. 20. The terminal management server program according to claim 19, which is characterized in that. 21. A computer, other than the participating terminals, if the computing means calculates the total of the minimum guaranteed amount allocated to the participating terminals and the total is less than the network resources necessary for content distribution. 18. A reminder means for urging a terminal to request content distribution, and further function.
The terminal management server program according to any one of 0. 22. A calculating means for calculating the total of the minimum guaranteed amount allocated to the participating terminals by the computer, and if the total exceeds the network resource amount necessary for content distribution, the excess amount is calculated as The terminal management according to any one of claims 17 to 21, wherein the terminal management means further functions as excess notification means for notifying the network resource control device to be additionally allocated to terminals other than participating terminals. Server program. 23. The computer further comprises: storage means for temporarily storing the content distributed from the content distribution server device, and content transmission means for transmitting the stored content in response to a request from a terminal. 23. The terminal management server program according to claim 17, wherein the terminal management server program is executed. 24. An encryption key acquisition means for negotiating an encryption key with a content distribution server device to acquire the encryption key, and an encryption key notification means for notifying the participating terminal of the acquired encryption key. The terminal management server program according to any one of claims 17 to 23, which further functions as a terminal management server. 25. A computer-readable storage medium storing the terminal management server program according to any one of claims 20 to 24.