JP2008283571A - Content distribution device, system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To further reduce a waiting time until reproduction is started when content data are sequentially reproduced from the divided content data whose reception is completed. <P>SOLUTION: A HGW device 1 divides content into a plurality of blocks, transmits the divided blocks to a mobile machine 2, and is provided with: a division processing part 16 which divides blocks B4, B5 ... after the predetermined number of blocks B1-B3 from the initial block B1 to be transmitted first to be predetermined size p and divides the predetermined number of blocks B1-B3 from the initial block B1 so as to be smaller than the predetermined size; and an acquisition control part 17 which sequentially transmits the blocks divided by the division processing part 16 to the mobile machine 2. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a content distribution apparatus, a content distribution system, and a content distribution method for dividing content into a plurality of blocks and transmitting the content to a content reproduction terminal.

When downloading large-capacity content such as videos and music from a base unit such as a server to a mobile unit such as a mobile device, the content data is divided and transmitted to the slave unit by the base unit, and the efficiency of data transmission / reception processing Has been made to improve. For example, in the wireless communication system disclosed in Patent Document 1 below, the master unit divides the content data into fragments of a certain size, sends a predetermined number of fragments as a sequence to the slave unit, and receives from the slave unit The result is received and resent if there is an unreceived fragment. As a result, the content data can be efficiently downloaded to the slave unit.
JP 2007-60145 A

  However, using the above technique, for example, when playing back sequentially from a fragment that has been received, such as streaming playback, the longer the fixed size of the received fragment, the longer the waiting time until playback starts, etc. There is a problem that the degree of becomes large.

  Accordingly, an object of the present invention is to shorten the waiting time until the reproduction is started and further reduce the degree of delay when sequentially reproducing the divided content data after completion of reception. .

  A content distribution apparatus according to the present invention is a content distribution apparatus that divides content into a plurality of blocks and transmits the divided blocks to a content reproduction terminal. After a predetermined number of blocks from the first block to be transmitted first, the content distribution apparatus has a predetermined size And dividing means for dividing the predetermined number of blocks from the head block so as to be smaller than a predetermined size, transmitting means for sequentially transmitting the blocks divided by the dividing means to the content reproduction terminal, It is characterized by providing.

  A content distribution system according to the present invention includes the above-described content distribution device and a content reproduction terminal.

  The content distribution method according to the present invention is a content distribution method using a content distribution apparatus that divides content into a plurality of blocks and transmits the divided blocks to a content reproduction terminal, and a predetermined number of blocks from the first block to be transmitted first. After the block, the content is divided into a predetermined size, and a predetermined number of blocks from the first block are divided so as to be smaller than the predetermined size, and the blocks divided in the division step are played in order. And a transmission step for the content distribution apparatus to transmit to the terminal.

  Thus, in the above invention, first, the first block to be transmitted first is divided and transmitted so as to have a predetermined size after a predetermined number of blocks. Also, a predetermined number of blocks from the head block are divided and transmitted so as to be smaller than a predetermined size. For this reason, when playing back sequentially from the blocks that have been received, the predetermined number of blocks from the first block to be transmitted first are divided so as to be smaller than the predetermined size, so they are received first. It is possible to shorten the waiting time from the first block until playback is started. As a result, the degree of delay can be further reduced.

  In addition, it is preferable that the dividing unit divides the predetermined number of blocks from the head block so as to increase in order from the head block. Since a predetermined number of blocks from the first block are divided so as to increase in order from the first block, it is possible to more reliably perform reproduction without delay.

  The content distribution apparatus according to the present invention further includes format conversion means for converting the content into a format that can be played back when received by the content playback terminal, and the dividing means performs content conversion processing by the format conversion means. It is also preferable to perform the division processing into blocks sequentially from the completed portion in parallel with the conversion processing by the format conversion means. Thereby, the division | segmentation process by a division | segmentation means can be performed in parallel with the conversion process by a format conversion means. As a result, it is possible to efficiently perform division processing and conversion processing.

  According to the present invention, it is possible to shorten the waiting time until the reproduction is started and further reduce the degree of delay when sequentially reproducing the divided content data from the completion of reception.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. In the description of the drawings, if possible, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  First, the configuration of the content distribution system according to the embodiment will be described. FIG. 1 is a diagram illustrating a configuration of a content distribution system according to the embodiment. The content distribution system 100 includes an HGW (Home Gateway) device 1 (content distribution device) and a mobile device 2 (content reproduction terminal). Note that a communication network (not shown) is provided between the HGW device 1 and the mobile device 2 to relay communication between them. The communication network includes a mobile communication network, a LAN (that is, a local area network), a WAN (that is, the Internet), and the like. In addition, although the number of each of the HGW apparatus 1 and the mobile devices 2 is usually plural, FIG. 1 shows one each.

  Here, the HGW apparatus 1 divides the content data into a plurality of blocks and transmits the blocks to the mobile device 2 or enables the mobile device 2 to download the blocks, thereby moving the content data. It is a device such as a server or a host computer distributed to the machine 2. The HGW apparatus 1 is managed by a content production company, a communication company, or the like. The physical configuration and functional configuration of the HGW apparatus 1 will be described later.

  The mobile device 2 is a terminal such as a mobile phone having a function of sequentially reproducing a plurality of blocks received from the HGW device 1. The mobile device 2 may be a terminal such as a personal computer or a PDA as long as the terminal has such a function. The physical configuration and functional configuration of the mobile device 2 will be described later.

  Here, examples of the content data include moving image video files such as dramas, movies, and TV programs, and audio files such as music, melody, and radio programs.

  Next, the hardware configuration of the HGW apparatus 1 according to the embodiment will be described. FIG. 2 is a diagram illustrating a hardware configuration of the HGW apparatus 1 according to the embodiment. The HGW apparatus 1 includes a CPU 101 (Central Processing Unit), a RAM 102 (Random Access Memory) and a ROM 103 (Read Only Memory) that are main storage devices, a communication module 104 for performing communication, an auxiliary storage device 105 such as a hard disk, and the like. It is comprised as a computer provided with the hardware. The function of the HGW apparatus 1 is exhibited by the operation of these components.

  Next, the functional configuration of the HGW apparatus 1 according to the embodiment will be described. As shown in FIG. 1, the HGW apparatus 1 includes, as functional components, a content storage unit 11 (content storage unit), an external NW connection unit 12 (external connection unit), and a storage unit 13 (storage unit). A temporary storage unit 14 (temporary storage unit), a transcode processing unit 15 (format conversion unit), a division processing unit 16 (division unit), and an acquisition control unit 17 (transmission unit).

  The content storage unit 11 is a part that holds content data to be reproduced and viewed by the user of the mobile device 2. That is, it is an area for storing multimedia data such as content data such as the above-mentioned moving image file and content data such as music file. All content data to be stored is stored in association with “request content ID” uniquely assigned to each data. The content storage unit 11 may not be provided in the HGW device 1 but may be provided in a device different from the HGW device 1 so that the other device functions as a media server.

  The external NW connection unit 12 is a part that performs transmission / reception of data with the mobile device 2 that is a request source of distribution, reproduction, and viewing of content data, and control of communication including this transmission / reception. When the external NW connection unit 12 accepts the content data distribution request from the mobile device 2, the “requested content ID” of the content data requested for distribution and the location in the content data where viewing starts (for example, the first content data From the mobile device 2, and stores the information in the storage unit 13. In addition, when the content data that has been converted and divided as described later is stored in the temporary storage unit 14, the external NW connection unit 12 transmits the processed data to the mobile device 2.

  The storage unit 13 is a part that stores and holds the “requested content ID” and “conversion processing start position” and “the number of variable-size blocks” described later. The “conversion processing start position” is also information indicating a position at which a transcoding processing unit 15 described later starts content data conversion processing. The “number of variable-size blocks” is information indicating the number of variable-size blocks generated by content data division processing by the division processing unit 16 described later. The storage unit 13 stores information on “request content ID” and “conversion processing start position” transmitted from the mobile device 2. The “conversion processing start position” and the “number of variable-size blocks” are updated to new information every time content data division processing is performed by the division processing unit 16.

  The temporary storage unit 14 is a part that temporarily holds and stores the content data stored in the content storage unit 11 in order to perform conversion processing and division processing. Content data acquired from the content storage unit 11, converted content data output from the transcode processing unit 15, and data such as blocks generated by the division processing of the division processing unit 16 are stored in the temporary storage unit 14. Is done. The temporary storage unit 14 has a function of outputting these data in response to a request from the acquisition control unit 17.

  The transcode processing unit 15 is a part that converts the format of the content data into a format that can be reproduced by the mobile device 2. When the information of “request content ID” and “conversion processing start position” transmitted from the mobile device 2 is stored in the storage unit 13, the transcode processing unit 15 starts the conversion processing from the acquisition control unit 17. The request is accepted and the above conversion process is started. The transcode processing unit 15 performs format conversion processing on the content data stored in the temporary storage unit 14 from the position indicated by the “conversion processing start position” to the end portion (end portion) of the content data. (Transcode conversion processing) is performed.

  The division processing unit 16 is a part that performs a process of dividing the content data that has undergone format conversion processing into blocks of a size that can be received for a long time by the mobile device 2. The division processing unit 16 divides the first block to be transmitted first after a predetermined number of blocks into a predetermined size p. Further, the division processing unit 16 divides a predetermined number of blocks from the first block to be transmitted first so that it is smaller than the predetermined size p. Here, when there are a plurality of a predetermined number of blocks from the first block to be transmitted first, it is preferable to divide the predetermined number of blocks from the first block so as to increase in order from the first block. Here, the division processing unit 16 sequentially performs the division processing into blocks in parallel with the format conversion processing from the part where the content conversion processing by the transcode processing unit 15 is completed. Details of the division processing by the division processing unit 16 will be described later.

  The acquisition control unit 17 is a part that sequentially transmits the blocks divided by the division processing unit 16 to the mobile device 2 via the external NW connection unit 12. When acquiring the content data from the content storage unit 11, the acquisition control unit 17 stores the content data in the temporary storage unit 14 to perform conversion processing and division processing, and outputs them to the mobile device 2 in order from the block in which these processing is completed. When the external NW connection unit 12 accepts the content data distribution request from the mobile device 2, the acquisition control unit 17 refers to the requested content ID in the storage unit 13 and collates with the content data in the temporary storage unit 14. Do. If the corresponding content data does not exist in the temporary storage unit 14, the corresponding content data is obtained by copying from the content storage unit 11 and stored in the temporary storage unit 14. The content data stored in the temporary storage unit 14 is output to the transcode processing unit 15 and subjected to conversion processing, and then divided by the division processing unit 16. When the processed content data, that is, the block from the division processing unit 16 is stored in the temporary storage unit 14, the acquisition control unit 17 sequentially transmits the processed block to the mobile device through the external NW connection unit 12. .

  Next, details of the division process will be described. FIG. 3 is an explanatory diagram for explaining details of the division processing by the division processing unit 16. The division processing unit 16 performs division processing using information on “conversion processing start position” and “number of variable-size blocks” stored in the storage unit 13. First, when the division processing unit 16 receives a request to start conversion and division processing of specific content data D from the acquisition control unit 17, the transcoded conversion part (that is, the shaded portion) of the corresponding content data D in the temporary storage unit 14 is received. Content data D is divided. At this time, the position where the conversion process has been completed and the division process is started is a “conversion process start position” R requested to be reproduced by the mobile device 2, and the content data D to be divided and cut out as a block The division size is determined by “the number of variable size blocks”. The division size will be described later. If the transcode conversion process is not completed within the range cut out by the division, the division process is performed after waiting for the conversion process to be completed.

  There are two types of sizes divided into blocks, a fixed size and a variable size. The fixed size is a fixed size (hereinafter referred to as p) determined by the specifications of the mobile device 2 or the user of the mobile device 2. The variable size is a size determined by the “number of variable size blocks”, and the closer to the end of the file of the content data D, the larger the division size. In other words, the closer to the beginning of the file, the smaller the division size.

  More specifically, the division processing unit 16 starts from the first block B1 to be transmitted first to a predetermined number of blocks (ie, “variable size block number”, for example, 3 here) (that is, B1 to B3 here). The division process is performed so that the variable size is smaller than the predetermined size. Further, the division processing unit 16 performs a division process so that a predetermined size p is reached after a predetermined number of blocks from the top block (that is, B4, B5,... Here). More specifically, the division size of the block generated and extracted by the n-th division is s (n), and the block after the “number of variable-size blocks k (ie, k = 3 here)” (ie, B4 here). , B5,...) Is switched to a fixed size p, a block satisfying the relational expression (1 ≦) n ≦ k (that is, k = 3 here) is divided into “variable sizes”. With respect to the division size s (n), a relational expression of s (n−1) ≦ s (n) ≦ s (n + 1) holds. In addition, in a block in which the relational expression of n> k (that is, k = 3 in this case) is established, the division is performed with “fixed size”. With regard to the division size s (n) at this time, s (n) = p The relational expression is established.

  The blocks generated by the division processing unit 16 are temporarily stored in the temporary storage unit 14 as processed content data. Each time the division processing by the division processing unit 16 is performed, the information on the number of variable size blocks and the conversion processing start position stored in the storage unit 13 is updated.

  Next, an example of the operation of the HGW apparatus 1 that performs content data format conversion processing, division processing, and distribution processing will be described. FIG. 4 is a flowchart for explaining an example of the operation of the HGW apparatus 1. The processing shown in this flowchart is mainly performed by the CPU 101, and is repeatedly executed at a predetermined timing from when the HGW device 1 is turned on until it is turned off.

  Here, as an example, assume that “the number of variable-size blocks” is 3, and the variable size s (n) is determined by p × n × 0.25 (where 1 ≦ n ≦ k (that is, k = here). (3) When the relational expression is satisfied). That is, if content data of a fixed size p is a video file with a playback time of 300 seconds, it is divided into 75 second sizes as the first block B1 transmitted first (ie, n = 1), and the second time (ie, The block B2 transmitted at n = 2) is divided at a size of 150 seconds, and the block B3 transmitted at the third time (ie, n = 3) is divided at a size of 225 seconds. The blocks B4, B5,... Transmitted after the fourth time are all divided by a fixed size of 300 seconds. The above definition formula for determining the variable size s (n) is an example of a division method and does not limit the present invention. As described above, the content data may be divided by dividing the reproduction time. However, as another example, the content data may be divided according to the file capacity of the content data, the number of frames, or the like.

  As shown in FIG. 4, when a user selects content desired to be viewed from a list showing a list of content displayed on the mobile device 2, the mobile device 2 requests the HGW device 1 to view the content. Information is sent. Then, the external NW connection unit 12 of the HGW apparatus 1 receives this viewing request information and holds it in the storage unit 13 (step S01). The viewing request information includes “request content ID” and “conversion processing start position” of the content selected by the user. Here, the acquisition control unit 17 determines whether or not the requested content has not been requested for viewing by the user so far, that is, whether or not it is the first viewing request ( Step S02). In step S02, the acquisition control unit 17 determines whether the content data remains in the temporary storage unit 14 as a cache. If the content data does not remain as a cache, it is determined that the request is for the first time viewing. If the content data remains in the cache, it is determined that the request is not the first viewing request.

  In step S02, when the current viewing request is the first viewing request, the acquisition control unit 17 acquires content data corresponding to the “requested content ID” from the content storage unit 11 and stores it in the temporary storage unit 14 ( Step S03). Then, the acquisition control unit 17 requests the transcode processing unit 15 to convert the content data stored in the temporary storage unit 14. Thereby, the transcode processing unit 15 starts transcoding conversion processing of content data from the “conversion processing start position” (step S04). Then, the process proceeds to step S05.

  On the other hand, in step S02, if the current viewing request is the second or later and is not the first viewing request, that is, if viewing requests have been made by this user so far (for example, playback from the previous viewing end portion). In the case of or a request for changing the playback position such as rewinding), since the content data remains in the temporary storage unit 14 as a cache, step S03 is omitted and the process proceeds to step S04.

  In step S05, the division processing unit 16 determines whether or not the division count number is equal to or less than the “variable size block number k” (that is, k = 3 here). Here, the division count number is the total number of times content data division processing has been performed. When the division count number is equal to or less than “variable size block number k” (that is, k = 3 in this case), as described above, the variable size s (n) is determined by p × n × 0.25 (step S06). ). In this example, as described above, the division size at the first division is ¼ of the fixed size p, the second division size is ½ of the fixed size p, and the third division size is It is 3/4 of the fixed size p. Next, the process proceeds to step S07.

  In step S07, the division processing unit 16 determines whether or not the transcode conversion processing has been completed up to the point where division is performed in order to generate a block having the division size determined as described above. In step S07, when the transcode conversion processing is not completed up to the point where the division is performed in order to generate the block of the division size determined as described above, and the division processing cannot be performed, the division processing unit 16 performs the predetermined time. Only after waiting (step S08), the process proceeds to step S07 again.

  On the other hand, if the transcode conversion process has been completed up to the point where the division is performed in order to generate the block having the division size determined as described above in step S07, and the division process is possible, the designated division size is used. The content data is divided and cut out (step S09, division step). Then, the division count number is updated (step S11). The division count is incremented by one every time division processing is performed once. Then, the process proceeds to step S12.

  In step S05, if the division count number is not less than or equal to “variable size block number k” (that is, k = 3 in this case), that is, the number of blocks indicated by “variable size block number k” has already been divided. If it is generated, as described above, the division size is determined as the fixed size p (step S10). Then, the process proceeds to step S09.

  In step S12, the acquisition control unit 17 transmits the block cut out by dividing the content data to the mobile device 2 via the external NW connection unit 12 (transmission step). Then, the process proceeds to step S13.

  In step S13, the acquisition control unit 17 determines whether the conversion process and the division process are completed up to the end of the content data and all the blocks have been transmitted to the mobile device 2 (step S13). When the conversion process and the division process are not completed up to the end of the content data, or when there is a block that has not been transmitted to the mobile device 2, the process proceeds to step S06. On the other hand, when the conversion process and the division process are completed and all the blocks are transmitted to the mobile device 2, the series of processes ends at this point. However, if an interrupt request such as a new viewing request is generated during this series of processing, the processing being executed is interrupted and new processing is performed.

  As described above, in the HGW apparatus 1, the content distribution system 100, and the content distribution method according to the present invention, as shown in FIG. 3, a large amount of content data D is divided into a plurality of blocks and transmitted to the mobile device 2. To do. More specifically, first, a predetermined size p is set after a predetermined number (three in this case) of blocks (that is, B1 to B3) after the first transmission block B1 (that is, B4, B5,... Here). The data is divided and transmitted to the mobile device 2. In addition, a predetermined number (three in this case) of blocks (that is, B1 to B3) from the first block B1 are divided so as to be smaller than a predetermined size p and transmitted to the mobile device 2. For this reason, when the mobile station 2 connects the blocks that have been received, and sequentially reproduces them, a predetermined number (three in this case) of blocks (ie B1 to B1) from the first block B1 transmitted first. Since B3) is divided so as to be smaller than the predetermined size p, it is possible to shorten the waiting time until playback is started from the block B1 received first. As a result, the degree of delay can be further reduced, and a large amount of content data can be reproduced without a sense of incongruity.

  Note that the time from when the viewing of content is requested by the mobile device 2 to when playback on the mobile device 2 is started decreases as the size of the divided blocks decreases. However, when large-sized content data is divided into blocks of small size units, the number of blocks that are divided data to be transmitted to the mobile device 2 increases. Here, since the block that is the divided data needs to have header information or the like individually, the total transmission amount of the data transmitted to the mobile device 2 becomes larger than the data capacity before the division as the division number increases. .

  In contrast, in the HGW apparatus 1, the content distribution system 100, and the content distribution method according to the present invention, the division size gradually increases in the first predetermined number of divisions (that is, the number indicated by the variable size block number). Data division processing is performed such that the data is divided at a variable size and then is divided at a fixed size p. For this reason, while effectively utilizing the resources of the network between the HGW apparatus 1 and the mobile device 2, the playback delay in the mobile device 2 can be reduced as much as possible, and the playback can be performed more reliably and without delay. In addition, since transcoding conversion processing such as conversion of general content data to a mobile phone playback format is performed in parallel with the division processing, the division processing and conversion processing can be performed efficiently. Real-time distribution of large-capacity content data in the format is possible.

  Examples of the present invention will be described below, but the present invention is not limited thereto. A mobile phone belonging to the 902iS series is used as the mobile device 2 (the playback player has been remodeled so that content data can be played back for a long time). A personal computer was used. As content data, audio (64 kbps / 48 kHz) having a bit rate of 96 and a frame of 15 was used. Further, the MPEG2 format content data before the format conversion process (that is, before the transcoder) is converted to the 3GP format after the format conversion process (that is, after the transcoder).

  When this content data is divided by the personal computer PC-AX50M every 30 seconds from the first transmission and transmitted to the mobile phone SH902iS via the communication network, the display start time until the display is started is 61. It was 9 seconds.

  On the other hand, the content data is first transmitted from the first 5 seconds (B1), 10 seconds (B2), 20 seconds (B3), 30 seconds (B4), 30 seconds (B5), 30 seconds. When (B6),... (Hereinafter, fixed size of 30 seconds) is transmitted by the PC PC-AX50M and transmitted to the mobile phone SH902iS, the display start time until the display is started is 26.6 seconds. The degree of delay could be made smaller than in the case of 61.9 seconds.

  Similarly, from the first transmission, 10 seconds (B1), 15 seconds (B2), 20 seconds (B3), 25 seconds (B4), 30 seconds (B5), 30 seconds (B6),. In this case, the display start time is 37.5 seconds, and the degree of delay can be made smaller than in the case of 61.9 seconds.

  Similarly, from the first transmission, 10 seconds (B1), 20 seconds (B2), 30 seconds (B3), 30 seconds (B4), 30 seconds (B5), 30 seconds (B6),. In this case, the display start time is 35.1 seconds, and the degree of delay can be made smaller than in the case of 61.9 seconds.

  Similarly, from the first transmission, 15 seconds (B1), 20 seconds (B2), 25 seconds (B3), 30 seconds (B4), 30 seconds (B5), 30 seconds (B6),. In this case, the display start time is 44.5 seconds, and the degree of delay can be made smaller than in the case of 61.9 seconds.

  Similarly, from the first transmission, 20 seconds (B1), 25 seconds (B2), 30 seconds (B3), 30 seconds (B4), 30 seconds (B5), 30 seconds (B6),. In this case, the display start time is 51.5 seconds, and the degree of delay can be made smaller than in the case of 61.9 seconds.

It is a figure which shows the structure of the content delivery system which concerns on embodiment. It is a figure which shows the hardware constitutions of the HGW apparatus which concerns on embodiment. It is explanatory drawing explaining the detail of the division process by a division process part. It is a flowchart explaining operation | movement of the HGW apparatus which concerns on embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... HGW apparatus, 2 ... Mobile station, 11 ... Content storage part, 12 ... External NW connection part, 13 ... Memory | storage part, 14 ... Temporary storage part, 15 ... Transcode process part, 16 ... Division | segmentation process part, 17 ... Acquisition Control unit 100 ... content distribution system 104 ... communication module 105 ... auxiliary storage device B1-B5 ... block D ... content data.

Claims (5)

A content distribution device that divides content into a plurality of blocks and transmits the content to a content playback terminal,
The first block to be transmitted first is divided to a predetermined size after the predetermined number of blocks, and the predetermined number of blocks from the first block is divided to be smaller than the predetermined size. Means,
Transmitting means for sequentially transmitting the blocks divided by the dividing means to the content reproduction terminal;
A content distribution apparatus comprising: The dividing unit divides the predetermined number of blocks from the head block so that the predetermined number of blocks increases in order from the head block.
The content distribution apparatus according to claim 1, Further comprising format conversion means for converting the content into a format that can be played back when received by the content playback terminal;
The dividing means sequentially performs the division processing into the blocks in parallel with the conversion processing by the format conversion means from the part where the conversion processing of the content by the format conversion means is completed.
The content distribution apparatus according to claim 1, wherein the content distribution apparatus is a content distribution apparatus. The content distribution device according to any one of claims 1 to 3,
The content playback terminal;
A content distribution system comprising: A content distribution method using a content distribution apparatus that divides content into a plurality of blocks and transmits the content to a content reproduction terminal,
The first block to be transmitted first is divided to a predetermined size after the predetermined number of blocks, and the predetermined number of blocks from the first block is divided to be smaller than the predetermined size. Steps,
A transmission step in which the content distribution device sequentially transmits the blocks divided in the division step to the content reproduction terminal;
A content distribution method comprising:

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