JP2002026828A - Divided transmission/reception system of mass data - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the divided transmission/reception system of mass data, capable of distributing data in a short time and improving receiving efficiency. SOLUTION: A contents distribution center on an upstream side being a distribution server is provided with at least divided processing part 8, a plural- times continuous transmission instruction part 9, a memory 10 with a contents file Hi (for one week, e.g.) stored therein and a memory 11 with a connection managing file Bi stored therein. A reception server in a shop on a downstream side is provided with a memory 11, a memory 12, a reception error decision processing part 13, an error place fetching processing part 14 and a block combination processing part 15. A distribution center 1 divides the contents file being a data service for one week., e.g., into blocks for prescribed time and transmits this divided file to the receiving server 5 in the shop on the down stream side through a CS transmission antenna 2 and a communication satellite 3 to improve the receiving efficiency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to satellite broadcasting (BS,
The present invention relates to a division transmission / reception system for large-capacity data multiplex broadcasting in an existing broadcasting system such as CS (CS) or terrestrial (TV, FM).

[0002]

2. Description of the Related Art In general, a data multiplex broadcasting system adopts a one-way communication system from a broadcasting station to each receiving terminal, and a plurality of program files (hereinafter simply referred to as files) are simultaneously transmitted to each receiving terminal. Sending in the direction.

[0003] When transmitting in this manner, a receiving error may occur on the receiving side. However, if the receiving terminal on the downstream side does not use the uplink line, the occurrence of the reception error cannot be transmitted to the broadcasting station on the transmitting side. For this reason, the broadcasting station has to repeat the same file multiple times,
The transmission success rate was improved by transmitting to each receiving terminal on the downstream side.

[0004] On the other hand, there is a method in which retransmission can be requested when an error occurs during data reception on the receiving device side by using another communication means or the like (for example, telephone).

[0005] Even in such a case, a large-capacity file has been sent from the beginning. For example, as an example of CS data broadcasting, when transmitting a file of about 500 MB at a communication speed of about 1 Mbps, about one hour is required. When an error occurs during transmission, retransmission processing takes about one hour. It was hanging.

[0006]

However, in order to improve the reception efficiency as described above, the method of sending a large-capacity file a plurality of times requires transmitting a large-capacity file from the beginning each time. There was a problem that it would take a long time.

[0007] In addition, the receiving side has to wait for that much, so that there is a problem that the distribution to the user is delayed accordingly.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has as its object to provide a large-volume data division transmission / reception system which can be distributed in a short time and has improved reception efficiency.

[0009]

According to a first aspect of the present invention, there is provided a transmission system for transmitting a main program and a large-capacity content file for a predetermined period from an upstream side to a downstream side via a network. While dividing the content file of the capacity in a predetermined time unit,
After generating combined management information of each divided file and transmitting the plurality of divided files and combined management information to the downstream side, the content file is divided and transmitted again.

[0010] When receiving the divided file from the upstream side, the downstream side extracts the divided file at the time of the next transmission corresponding to the file, and receives the retransmitted file. The gist of the invention is to combine the received divided files according to the combination management file upon completion.

According to the embodiment, in the transmission system in which the upstream distribution center transmits a main program and a large-capacity content file for a predetermined period to the downstream reception server, the upstream distribution center includes: Means for generating a divided file obtained by dividing a content file of a predetermined time unit by the number of divisions and sequentially transmitting the divided files to the downstream side, and generating respective combined management information at the time of generating the divided file; Means for transmitting to the downstream side, and each time the plurality of divided files are transmitted, determine whether or not the number of transmissions reaches a preset number of transmissions, and until the number of transmissions is reached, Means for dividing the file again for transmission.

The downstream receiving server receives the divided file from the upstream side, and stores the divided file in correspondence with the number of transmissions.
It is determined whether or not the divided file has been successfully received. If the divided error file cannot be normally received, the identification information is extracted, and when the retransmission of the divided file is completed, the divided error file exists. Means for extracting divided files corresponding to the identification information at the time of retransmission and combining the divided files according to the combination management information.

According to a second aspect of the present invention, in the transmission system for transmitting a main program and a large-capacity content file for a predetermined period from the upstream side to the downstream side, the upstream side transmits the large-capacity content file in predetermined time units. In addition to sequentially dividing the file, a distribution schedule of the plurality of divided files in a predetermined period is generated, and a plurality of divided files and combined management information of the respective divided files are generated according to the distribution schedule and transmitted to the downstream side.

[0014] The downstream side receives and stores the divided files and the combined management information from the upstream side, and when receiving the last divided file among the divided files, it divides each divided file according to the combined management information. The point is to combine them.

According to a third aspect of the present invention, the upstream side includes means for transmitting the plurality of divided files and the combined management information to the downstream side, and then dividing and transmitting the content file again.

[0016] The downstream side receives the divided file from the upstream side and stores it in correspondence with the number of transmissions. For a divided error file having a reception error, the file is transmitted at the next transmission corresponding to the file. And a means for combining the divided file received according to the combination management file and the extracted divided file when the retransmission is completed.

According to a fourth aspect of the present invention, when the upstream side transmits the divided file according to the distribution schedule and interrupt data occurs, the upstream side transmits the divided file in the date and time zone at the time of occurrence of the interrupt to another date and time zone. And means for generating a new distribution schedule assigned to the interrupt data at the date and time zone at the time of occurrence of the interrupt.

According to a fifth aspect of the present invention, the downstream side and the upstream side are connected by another network different from the network, and when the downstream side detects a reception error, the downstream side transmits the identification code of the divided file of the reception error to the above-mentioned network. Means for transmitting to the upstream side via another network.

When the upstream side receives the identification code of the divided file of the reception error via the another network, the upstream side has means for transmitting the divided file of the identification code to the downstream side again. Make a summary.

According to a sixth aspect of the present invention, a main program and a large-capacity content file for a predetermined period are transmitted from a distribution center on the upstream side to a number of receiving servers in each downstream area via a wireless network. In a transmission system in which the distribution center and a number of reception servers for each area are connected by different networks, the downstream reception server receives the content file or a divided file obtained by dividing the content file in a predetermined time unit. Then, when any of the divided files has a reception error, a means for causing the reception server in a preset area to transfer the divided file or the content file of the reception error, and when the transfer is performed, The upstream distribution center consists of the destination name, date, and type of data transferred. The feed information and means for notifying via the network.

The upstream distribution center, when receiving the transfer information from the downstream distribution center, transfers a charge including a communication charge to the transfer destination and a transfer service charge to the receiving server in the area where the transfer is performed. And a means for paying to the owner.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS <Embodiment 1> FIG. 1 is a schematic configuration diagram of a large-volume data division transmission / reception system according to Embodiment 1 of the present invention. The divided transmission system shown in FIG.
S, CS) or terrestrial broadcasting (TV, FM), etc., in a data multiplex broadcast, etc. in an existing broadcasting system, a large-capacity data is divided into small-capacity data on the upstream side serving as a transmitting side, and transmitted. Then, the data divided by the downstream side is integrated to restore the original large-capacity data.

That is, the content distribution center 1 divides a content file, which is a data service for one week, for example, into blocks of a predetermined time, and receives the divided file via the CS transmitting antenna 2 and the communication satellite 3 for receiving data at a downstream store. The transmission to the server 5 improves the reception efficiency.

The content distribution center shown in FIG. 1 is a distribution server, and includes at least a division processing unit 8, a multiple-time continuous transmission instruction unit 9, a memory 10 storing content files Hi (for one week, for example), A memory 11 for storing a file Bi.

[0025] The division processing unit 8 includes a content file Hi.
Are sequentially divided into blocks from the beginning, and the identification code ABi of the divided file Ai (a1, a2,...)
(AB1, AB2,...) Are generated and added to each divided file. The smaller this divided file Ai is, the better,
If the size is too small, the number of divided files becomes too large. Therefore, a division size that can secure the reception probability described below to a certain value or more is adopted.

At this time, the division order numbers Di (d1, d1,
d2,...) are generated and stored as the combination management file Bi in association with the identification code ABi. This combination management file Bi is associated with a file name.

Then, the divided file Ai is divided into
It is transmitted to the downstream side via the broadcast antenna 2, and after the final divided file Ai (an), the stored combined management file Bi is transmitted.

The multiple-time continuous transmission instructing unit 9 counts the number of times of transmission of each divided file of the content file Hi,
Until the count reaches a preset number of hi times,
The content file Hi is sent to the division processing unit 8.

For example, the number of transmissions of the combined management file Bi is counted, and when the counted value becomes hi,
The transmission of the divided file of the file 10 is stopped.

The receiving server 5 on the downstream side is arranged, for example, in a store as shown in FIG. 1, and the receiving server 5 is configured to include at least the divided file Ai and the combined management file 11 (B
The memory 12 includes a memory 12 for storing i), a reception error determination processing unit 13, an error location extraction processing unit 14, and a block combination processing unit 15. That is, since the memory 12 receives the divided file Ai a plurality of times, the reception efficiency is improved.

The reception error determination processing unit 13 determines whether or not the divided file Ai stored in the memory has a reception error. If the reception error has occurred, the identification code of the divided file Aip is subjected to an error location extraction process. Notify part 14.

Every time the identification code ABiq of the divided file Aip in which the reception error has occurred is notified, the error location extraction processing unit 14 extracts the divided file Ai of the identification code ABiq from the memory 12 and extracts the block combination processing unit 15.
To send to. Also, the divided file A in which the reception error occurred
For the divided files other than the ip, the memory capacity can be effectively used by not performing the reception processing itself as already received data.

The block combining unit 15 combines the divided files a1, a2, a3,... Based on the combined management file Bi stored in the memory 12 and performs the error location extraction processing on the divided file Aip of the error location. The original content file Hi of the content distribution center 1 is generated by incorporating the divided file Aip from the unit 14.

The operation of the large data division transmission / reception system configured as described above will be described below.

First, the reception success rate of a file will be described. Generally, when a content file having a file size of n bits is transmitted once, the reception success rate is calculated by using the fact that the reception success rate for each bit is [1-BER (BER: code error rate)].

## EQU1 ## pl = (1.BER) ⁿ . The probability pel of reception failure is pel = 1.pl = 1. (1.BER) ⁿ .

FIG. 2 summarizes p1 and pe1 for each BER value for each file size.
Is the highest reception probability.

On the other hand, Equation 1 shows the reception probability when the content file Hi of each size is independently received.
When i is divided into 10 MB, in order to receive the entire original 500 MB content file Hi, it is necessary to receive all 50 divided files Ai.

That is, the probability of receiving all of the 50 divided files Ai in one delivery is equal to the probability of receiving a 500 MB content file Hi without dividing it. This is clear from the fact that even if the content file Hi is divided, the data amount of the entire content file Hi does not change.

One of the advantages of dividing the content file Hi is that, when a reception error occurs, only the portion where the error occurred during the second distribution need be received.

For example, in the receiving process when the content file Hi is not divided, as shown in FIG. 3A, when a receiving error occurs, the subsequent receiving process is not performed and the receiving process is performed as shown in FIG. As shown in ()), when the same content file Hi is sent from the head for the second time, it is received and stored again, and is sequentially taken out again from the head.

However, in the first embodiment, as shown in FIG. 4A, the distribution center 1 divides the content file Hi into blocks (divided file A
i), the transmission is performed, and the receiving server 5 stores the divided file Aip having a reception error at the time of transmission even in the memory 12A (for the first time: generated for each reception) as it is. The divided file Aip that has become unrecognized is determined, and as shown in FIG. 4B, a reception error occurs for the first time among the divided files sent to the memory 12B (for the second time: generated for each reception) for the second time. Then, only the divided file Aip is extracted.

In FIG. 4A, when the content file Hi is divided into 20 and transmitted, the first time, 9
An error occurs in the ninth divided file, and FIG. 4B shows that only the ninth divided file is extracted for the second time.

Specifically, when a reception error occurs,
The identification code of the divided file Aip is read at the first time, and the divided file A of the identification code ABiq is read at the second time.
Retrieve ip from memory.

As shown in FIG. 4, the reception probability when divided and transmitted twice is as shown in Equation 2.

The probability of success pl2 is a probability that reception is successful when a divided file (file size: n / d) is distributed twice. A content file having a file size of n bits is divided into d files and received when distributed twice. Is multiplied by the total number d of divided files.

[0046]

[Number 2] pd2 = [1- {1- (1 -BER) n / d} 2] d Similarly, the reception success probability pd3 when that delivered three times is as follows.

[0047] pd3 = [1- {1- (1 -BER) n / d} 3] d When it is transmitted by dividing the content file Hi at a predetermined time unit improves the probability of reception as shown in FIG. 5 are doing.

<Second Embodiment> FIG. 6 is a schematic configuration diagram of a large-volume data division transmitting / receiving system according to a second embodiment.

In the second embodiment, for example, a schedule can be set in which a divided file Ai of a content file Hi for one week can be distributed within one week without transmitting the divided file Ai at one time.
The divided file Ai is distributed according to this schedule.

The content distribution center 1 includes the same memories 11 and 10 as in the first embodiment, and a division processing unit 8. Further, the second embodiment includes a transmission schedule generation processing unit 20, a memory 21 in which a transmission schedule table Ki is stored, a transmission processing unit 22, and a calendar timer 23.

The transmission schedule generation processing unit 20 splits the content file Hi into divided files Ai (a1, a2,
...) And the respective volumes, the transmission schedule table Ki (transmission date, time zone, divided file (also referred to as divided data) name and the like) over a plurality of days for one week of each divided file. Is generated, and this is stored in the memory 21.

The transmission schedule generation processing section 20
Generates the transmission schedule table Ki if a later interruption occurs after the transmission schedule table Ki is generated.

The transmission processing section 22 transmits the transmission schedule table K
Every time i is generated, the divided file Ai is transmitted according to the schedule.

The divided transmission / reception system for large data according to the second embodiment configured as described above will be described with reference to FIG.

As shown in FIG. 7, the transmission period of the main program is assigned from 0:00 to 14:00 on each day.

Then, when the transmission schedule table Ki is generated as shown in FIG. 8A, the transmission processing unit 22 sets the calendar timer 23 to the transmission schedule table Ki.
When the time comes, the divided file Ai is transmitted.

For example, at 14:00 on the first day, the transmission processing unit 22 transmits the divided file a1 divided by the division processing unit 8 to the receiving server 5 via the CS transmitting antenna 2 and the communication satellite 3.

At 18:00 on the first day, the transmission processing unit 22 transmits the divided file a2 divided by the division processing unit 8 to the receiving server 5 via the CS transmitting antenna 2 and the communication satellite 3. .

Such processing is performed for one week. 7A and FIG. 8A, all divided files a on the fourth day
The transmission of 1, a2,... A8 is completed.

When the division file a8 is transmitted, the combination management file Bi from the division processing unit 11 is transmitted.

On the other hand, the receiving server 5 at the store stores the divided files a1, a2,... A8 in the memory 12 when the divided files a1, a2,. In the schedule table Ki of FIG. 8A of the second embodiment, the last divided file a8 is transmitted in five days.

Then, upon receiving the connection management file Bi, the block connection processing unit 15 of the reception server 5 reads the divided files a1, a2,... A8 having the identification code of the connection management file Bi, and reads the connection management file Bi. Are combined according to the combination information indicated by.

That is, a large content file Hi
Is divided and transmitted over a plurality of days, so that even a very large content file can be distributed without affecting the transmission time zone of the main program.

When the interrupt data Gi is generated, for example, at 17:00 on the third day, the transmission schedule generation processing unit 20 distributes the divided file a5.
After the divided file a5 is distributed as it is, as shown in FIG. 8B, the divided data a6 on the third day is moved and assigned to the time zone from 14:00 to 18:00 on the fifth day, and The interrupt data Gi is allocated from 18:00 to 24:00 on the third day.

As a result, as shown in FIG. 9, the transmission processing section 22 sets the calendar timer 23 to the third day 18:
As soon as 00 is measured, the interrupt data Gi is transmitted. Then, at 14:00 on the fifth day, the moved divided file a6 is transmitted.

<Third Embodiment> FIG. 10 is a schematic configuration diagram of a large-volume data division transmitting / receiving system according to a third embodiment. In the third embodiment, when the divided file Ai is transmitted while being divided into a plurality of time zones, the divided file is continuously transmitted plural times.

That is, as shown in FIG. 10, when the transmission processing unit 22 transmits the divided file Ai based on the transmission schedule table Ki, the division transmission instruction processing unit 9 is activated and the division processing unit 8 is activated again. Content file Hi
And the transmission processing unit 22 transmits these divided files again. In this description, the transmission is divided into two.

Then, each time the receiving server 5 of the store transmits the divided file, the memory 12A (for the first time) is generated and the divided file is stored.

The memory 12B is generated and stored every time the second divided file is transmitted.

Then, the reception error judgment processing section 13 judges whether or not the divided file Ai stored in the memory 12A has a reception error. If the reception error has occurred, the identification code of the divided file Aip is changed to an error. The location extraction processing unit 14 is notified.

Each time the identification code ABiq of the divided file Aip in which the reception error has occurred is notified, the error location extraction processing unit 14 sends the identification code ABiq from the memory 12B.
Block division processing unit 1
5

The block combination processing unit 15 combines the divided files a1, a2, a3,... Based on the combination management file Bi stored in the memory 12 and performs the error location extraction processing on the divided file Aip of the error location. The original content file Hi of the content distribution center 1 is generated by incorporating the divided file Aip from the unit 14.

Therefore, when the divided file is transmitted over a plurality of hours based on the transmission schedule table Ki, the content file is divided and transmitted again, so that the receiving efficiency is improved and efficient distribution is possible.

<Fourth Embodiment> FIG. 11 is a schematic configuration diagram of a large-volume data division transmitting / receiving system according to a fourth embodiment. In the fourth embodiment, a divided file Ai having an error
Only p is retransmitted.

As shown in FIG. 11, the content distribution center 1 includes an error data retransmission instruction unit 26. The error data retransmission instruction unit 26 transmits an error data from the downstream receiving server 5 to the upstream side via the network 28. The transmission processing unit 22 is notified of the identification code ABiq of the divided file Aip in which the reception error has occurred.

The transmission processing unit 22 extracts from the division processing unit 8 the division file Aip of the identification code ABiq of the division file Aip in which the notified reception error has occurred, via the CS broadcasting antenna 2 and the communication satellite 3. To send.

The receiving server 5 on the downstream side has an error data transfer instructing unit 27, and the divided file Aip that the receiving error determination processing unit 13 has determined to be a receiving error at the time of the first transmission.
And transmits it to the upstream side via the network.

That is, as shown in FIG. 12, the upstream division processing section 8 divides the content file Hi into a plurality of pieces (S
1) and these divided files Ai (a1, a2,
..) Is generated (S2).

Next, the divided file Ai and the combined management file Bi are transmitted to the downstream side (S3). Then, the error data retransmission instructing unit 26 determines whether or not there is a retransmission request from the downstream side via the network (S4). If there is error data retransmission, the process shifts to step S3 to indicate the error data. Retransmit the split file.

On the other hand, the downstream side reserves reception of the combined management file Bi and the divided file Ai (S5). That is, it is waiting for reception.

Next, it is determined whether or not the combined management file Bi and the divided file Ai have all been received from the upstream side (S
6) If the reception has not been completed, a retransmission request is transmitted to the upstream side via the network (S7), and the process proceeds to step S7.
Return to 6.

When all the receptions have been completed in step S6, the divided files Ai (a1, a2,...) Are combined according to the combination management file Bi (S8).

Therefore, since only the location of the reception error is transmitted by the upstream side, the communication time can be further reduced and the communication cost can be reduced.

In the fourth embodiment, the divided file Aip in which an error has occurred is transmitted via a satellite line. However, the divided file Aip may be transmitted downstream via the network 28.

<Embodiment 5> Satellite broadcasting (BS, CS)
Alternatively, in existing broadcasting systems such as terrestrial broadcasting (TV, FM), communication errors often occur due to weather, geographical conditions, and the like. For example, the signal may not be received in the d region of the prefecture A in the Tohoku region, but may be received in the g region of the prefecture B. Therefore, the divided file received from the g area in the prefecture B is transferred using a network different from the line network.

For this reason, the receiving server 5 includes at least an error data transfer instructing unit 27 and a mirroring processing unit (not shown). For example, as shown in FIG. 27 (not shown)
Assigns the name of a local store (telephone number, network address, etc .: B store in g region of B prefecture) stored in advance when a reception error occurs, and receives the local store via the network. Error content file name and identification code ABi of divided file Aip
Send q and the transfer request code.

The B store in the g area in the B prefecture that received the
If the designated divided file Aip has been received, the divided file Aip is transmitted to the A store in the A prefecture d area A via the network.

When the transfer is completed, the mirroring processing unit of the reception server 5 of the store B in the g region in the prefecture B sends the transfer date and time, the transfer request date and time to the content distribution center 1.
Split file Aip name (Muroron content file Hi
May be transmitted) and the name of the store requesting the transfer (telephone number, ID, etc.). These are collectively referred to as reception error transfer information Fi in the present embodiment.

Upon receiving the reception error transfer information Fi, the content distribution center 1 determines a transfer service fee from the type of line used, the distance, the type of the divided file in which the reception error occurred, and the like. Transfer to the account of the store in B prefecture.

Therefore, when a reception error occurs in the store A in the prefecture A, the data is distributed from the store in the prefecture B without retransmission from the content distribution center 1, so that the communication cost can be reduced and the store to which the data is transferred is transmitted. Is a service fee.

However, the content distribution center 1 can retransmit on the wireless network in a situation where retransmission using the wireless network is cheaper, such as when a large number of reception errors occur on the downstream side. It is desirable to make a judgment such as

[0092]

As described above, according to the first aspect, the upstream side transmits a divided file obtained by sequentially dividing a large-capacity content file in a predetermined time unit and the combination management information to the downstream side, and the downstream side transmits the divided management file to the downstream side. The division error file that has resulted in the reception error is extracted at the next division transmission, and the division files are combined according to the combination management information when retransmission is completed.

Therefore, when an error occurs, it is only necessary to take in the divided file containing the error and combine it with the other divided files without receiving and taking in the large-capacity content file again from the beginning. There is an effect that the receiving efficiency is improved and a content file on the receiving side can be obtained in a short time.

According to the second aspect, the upstream side generates a distribution schedule for a plurality of divided files of the content file over a predetermined period, and distributes the divided files in accordance with the distribution schedule. When receiving the last divided file of the content file, the downstream side combines the content files according to the combination management information.

Therefore, there is an effect that even a very large content file can be efficiently distributed.

According to the third aspect, when transmitting the divided file based on the distribution schedule, the upstream side transmits the divided file again, so that even a very large content file can be distributed efficiently. This has the effect of improving the reception efficiency.

According to the present invention, when interrupt data is generated when the divided file is transmitted according to the distribution schedule, the divided file in the date and time zone at the time of occurrence of the interrupt is moved to another date and time zone, and The data generates a new distribution schedule assigned to the date and time zone at the time of occurrence of the interruption, and is transmitted according to the new distribution schedule.

[0098] For this reason, there is an effect that even if an interrupt occurs, distribution can be continued and efficiently performed.

According to the fifth aspect, when the downstream side detects a reception error, the identification code of the divided file of the reception error is transmitted to the upstream side via another network. Since only the file needs to be transmitted, the communication cost can be reduced and the retransmission time can be reduced.

According to a sixth aspect of the present invention, a distribution center on the upstream side and a number of receiving servers for each area on the downstream side are connected via a network different from the wireless network, and the receiving server in the area where the receiving error has occurred is determined in advance. Have the receiving server in another area transfer the split file of the receiving error.

Then, the owner of the receiving server in another area to which the data has been transferred is paid a charge including a transfer service charge and a call charge.

In other words, even if a reception error occurs, the divided file is transferred from another area that can be correctly received. Therefore, even if a reception error occurs, an error divided file can be obtained quickly and at low communication cost.

Further, since a fee is paid from the center to the owner of the server in the area to which the error division file has been transferred, the owner of the server in the area to which the error has been transferred is not bothered. Does not give any profit or loss.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a large-volume data division transmission / reception system according to a first embodiment.

FIG. 2 is an explanatory diagram illustrating a reception probability when the number of distributions is one;

FIG. 3 is an explanatory diagram illustrating a reception process when a file is not divided.

FIG. 4 is an explanatory diagram illustrating a reception process when a file is divided and distributed.

FIG. 5 is an explanatory diagram illustrating reception probabilities when divided distribution is performed.

FIG. 6 is a schematic configuration diagram of a large-volume data division transmitting / receiving system according to a second embodiment.

FIG. 7 is an explanatory diagram illustrating distribution based on a distribution schedule according to the second embodiment.

FIG. 8 is an explanatory diagram illustrating a distribution schedule table.

FIG. 9 is an explanatory diagram illustrating distribution based on a distribution schedule at the time of interruption.

FIG. 10 is a schematic configuration diagram of a large-volume data division transmission / reception system according to a third embodiment.

FIG. 11 is a schematic configuration diagram of a large-volume data division transmission / reception system according to a fourth embodiment.

FIG. 12 is a flowchart illustrating the operation of the fourth embodiment.

FIG. 13 is a schematic configuration diagram of a large-volume data division transmission / reception system according to a fifth embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Content distribution center 2 CS transmission antenna 2 3 Communication satellite 5 Receiving server 8 Division processing part 9 Multiple times continuous transmission instruction part 13 Reception error judgment processing part 14 Error location extraction processing part 15 Block connection processing part

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 7/08 H04N 7/08 Z 7/081 F term (Reference) 5B082 HA05 5C056 FA08 FA11 GA20 HA01 HA04 5C063 AA01 AB05 AC01 AC05 CA23 CA40 5K072 AA11 BB02 BB14 BB22 DD02 DD15 EE06

Claims (6)

[Claims] 1. A transmission system for transmitting a main program and a large-capacity content file for a predetermined period from an upstream side to a downstream side via a network, wherein the upstream side transmits the large-capacity content file in a predetermined time unit. And sequentially generate the combined management information of each divided file, and after transmitting the plurality of divided files and the combined management information to the downstream side, re-divide and transmit the content file, The side, when receiving the divided file from the upstream side, for the divided error file in which the reception error occurred, extracts the divided file at the next transmission corresponding to the file, and when the retransmission is completed, the connection management Splitting transmission / reception system for large data, characterized by combining received split files according to files Beam. 2. A transmission system for transmitting a main program and a large capacity content file for a predetermined period from an upstream side to a downstream side, wherein the upstream side sequentially divides the large capacity content file in a predetermined time unit. Together with generating a distribution schedule of the plurality of divided files in a predetermined period, generating a plurality of divided files according to the distribution schedule, generating combined management information of the respective divided files and transmitting the combined management information to the downstream side, Receiving and storing the divided file and the combined management information from the upstream side, and combining the divided files according to the combined management information when receiving the final divided file among the divided files. A large data division transmission / reception system. 3. The upstream side further comprises means for transmitting the plurality of the divided files and the combined management information to the downstream side, and then dividing and transmitting the content file again, wherein the downstream side comprises the upstream Receiving the divided file from the side and storing it in correspondence with the number of transmissions, and for a divided error file having a reception error, extracting a divided file at the next transmission corresponding to the file; 3. The system according to claim 2, further comprising means for combining the divided file received according to the combined management file and the extracted divided file when retransmission is completed. 4. When the upstream side transmits the divided file according to the distribution schedule, and interrupt data is generated, the upstream side moves the divided file in the date and time zone at the time of occurrence of the interrupt to another date and time zone. And means for generating a new distribution schedule assigned to the interruption data at the time and date when the interruption occurs.
A large-volume data division transmission / reception system as described. 5. The downstream side and the upstream side are connected by another network different from the network, and when detecting a reception error, the downstream side transmits the identification code of the divided file of the reception error to the other network. When the upstream side receives the identification code of the divided file of the reception error via the other network, the upstream side transmits the divided file of the identification code again, 5. The system according to claim 2, further comprising means for transmitting the data to the downstream side. 6. A main program and a large-capacity content file for a predetermined period are transmitted from an upstream distribution center to a large number of receiving servers in each downstream area via a wireless network, and a network different from the wireless network is provided. In the transmission system in which the distribution center and the plurality of receiving servers for each area are connected, the downstream receiving server receives the content file or a divided file obtained by dividing the content file in a predetermined time unit, Means for causing any of the divided files to have a reception error, transferring the divided file or content file of the reception error to a reception server in a preset area; and Transfer information including the transfer destination name, date, and type of transferred data is transmitted to the distribution center. Means for notifying via the network, the upstream distribution center, when receiving the transfer information from the downstream distribution center, the fee including the communication fee up to the transfer destination and the transfer service fee, Means for paying the owner of the receiving server in the area where the data was transferred.