JPH11313061A - Data distribution center device, data reception terminal device and data distribution system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data distribution system which can efficiently give a data retransmission request with respect to the transmission error of data transmitted from a data distribution center device through a broadcast line. SOLUTION: A reception error detection part 22 detects the transmission error of broadcast data received through a broadcast data block reception part 21. When a transmission error occurs, a probability retransmission request indication part 24 gives a retransmission request in terms of probability and the retransmission requests are prevented from being concentrated. A retransmission request terminal scale estimation part 15 estimates the number of terminals to which the retransmission requests are given. When the number of terminals is small, data are individually transmitted from a specified block retransmission part 17. When the estimation number of terminals is large, broadcast data are broadcast again from a rebroadcast interruption processing part 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data distribution system capable of simultaneously distributing data to a large number of receiving terminals via a broadcast line, and more particularly to an efficient data retransmission request for a data transmission error. The present invention relates to a data distribution system that can be used.

[0002]

2. Description of the Related Art In a conventional data distribution system, the same data is repeatedly transmitted in block units through a broadcast line. For data that did not reach the terminal due to a data transmission error, wait for the same data block to be broadcast again, or after data broadcasting has been completed,
A retransmission request was issued from the terminal side using an individual communication line, and a data block that could not be received was received. Also,
Instead of repeatedly transmitting the same data in block units, there has been a method using an error correction code.

[0003]

By the way, a transmission system to which an error correction code is added is effective when frequent transmission errors occur, but has a very good communication quality, such as ISDN multi-connection. When the frequency of occurrence of data transmission errors is low, the data transmission efficiency is deteriorated due to the high degree of redundancy, and therefore, it is often not used.

On the other hand, the method of repeatedly broadcasting data and waiting for the same data to be broadcast again when a data transmission error occurs has a very high transmission efficiency when there is almost no data transmission error. Become. However, when a data transmission error occurs, it is necessary to wait for the corresponding portion of all the data repeatedly broadcasted to be re-broadcasted. There must be. Furthermore, in a large-scale system having a large number of terminals receiving broadcasts, there is a problem that even if the communication quality is good, the possibility that at least one terminal cannot receive data increases.

Therefore, when a data transmission error occurs, a retransmission request is sent to the center device by individual communication, and a data block that could not be received is received.
The scale of the total number of terminals requesting retransmission differs depending on where in the multi-connection broadcast line a data transfer error occurs. FIG. 2 is a diagram illustrating a state in which a data transmission error has occurred in a path close to the receiving terminal. When a data transfer error occurs in a route close to a terminal, the number of terminals requesting retransmission is small. FIG. 3 is a diagram illustrating a state in which a data transmission error has occurred in a path close to the data distribution device. If a data transfer error occurs on a route close to the data distribution device, a large number of terminals will request retransmission. For this reason, there is a problem that retransmission requests are concentrated in the center device and congestion is caused in a serious case.

The present invention has been made in view of such circumstances, and the data distribution center apparatus estimates the total number of receiving terminals requesting retransmission, and many terminals request retransmission of the same data block. When the data block is re-broadcasted, and when a small number of terminals are requesting retransmission, data that could not be received by individual communication is sent, thereby avoiding the explosion of retransmission requests and efficiently transmitting data. It is an object of the present invention to provide a data distribution system capable of performing distribution.

[0007]

According to a first aspect of the present invention, there is provided a broadcast data storing means for storing broadcast data to be broadcast, and a data block transmitting means for broadcasting the broadcast data to a data receiving terminal device in block units. An individual retransmission request receiving unit that receives a retransmission request of a specific block stochastically made from the data receiving terminal device by individual communication,
A specific block retransmitting unit for individually transmitting the retransmitted specific block data to a data receiving terminal device; and estimating the total size of the data receiving terminal device requesting retransmission of the specific block from the number of retransmission requests for the specific block. Retransmission request terminal size estimating means, rebroadcasting determining means for determining whether to rebroadcast the data of the specific block based on the estimated total number of terminals, and information of the specific block for which rebroadcasting is determined. A rebroadcasting advance broadcast means for performing a preliminary broadcast, and a rebroadcast block interrupt processing means for rebroadcasting the specific block determined to be rebroadcasted are provided.

According to a second aspect of the present invention, there is provided a broadcast data block receiving means for receiving broadcast data in block units,
A reception error detection unit for checking whether there is a reception error in the broadcast data in block units, and a reception process after the specific block for a specific block which is not scheduled to be rebroadcast and needs to be retransmitted. Probabilistic retransmission request instructing means for instructing the start of a retransmission request operation in accordance with the probability value that increases with the probability, individual communication retransmission requesting means for notifying a data distribution center apparatus of a retransmission request for the specific block through a communication line, and the individual communication retransmission Individual communication data block receiving means for receiving a specific block requested to be retransmitted by the request means; block data assembling means for assembling and restoring the broadcast data received in block units; and for the specific block scheduled for rebroadcasting. Re-broadcast notice receiving means for receiving the information of

A third aspect of the present invention is characterized by comprising the data distribution center device according to the first aspect and a plurality of data receiving terminal devices according to the second aspect.

[0010] In a fourth aspect of the present invention, the retransmission requesting means of the data receiving apparatus detects the number of blocks D received after detecting a transmission error and a predetermined integer A (A
≧ 1) and the real number α (0 <α <1), the probability P
= Α ^(AD) is obtained, and an instruction to make a retransmission request is issued with this probability P, so that retransmission requests are not temporarily concentrated.

According to a fifth aspect of the present invention, in the data distribution center device, the terminal total number estimating means uses the number C of retransmission requests for a specific block and the probability P to receive a data transmission request for a retransmission request. The total number N of terminal devices is represented by N = (C /
P) -C, if the total number N of terminals exceeds a predetermined threshold, the specific block is rebroadcast.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A data distribution system according to one embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of the embodiment. In this figure, reference numeral 1 denotes a data distribution center device for transmitting broadcast data through a broadcast line and a communication line.
, A data block transmitting section 12, a rebroadcast block interrupt processing section 13, an individual retransmission request receiving section 14, a retransmission request terminal size estimating section 15, a rebroadcast deciding section 16, a specific block retransmitting section 17, And a broadcast announcement broadcast unit 18.

Reference numeral 2 denotes a data receiving terminal device for receiving data transmitted from the data distribution center device 1,
Broadcast data block receiver 21 and reception error detector 22
, A block data assembling unit 23, a stochastic retransmission request instructing unit 24, an individual communication retransmission requesting unit 25, an individual communication data block receiving unit 26, and a rebroadcast notice receiving unit 27.

Here, the data distribution system has a configuration in which a plurality (one or more) of data receiving terminal devices 2 are connected to the data distribution center device 1 via a broadcast line and a communication line. In FIG. 1, only one data receiving terminal device 2 is shown for convenience of explanation.

Next, an operation of transmitting and receiving data using the data distribution center device 1 and the data receiving terminal device 2 will be described with reference to FIG. The data block transmitting unit 12 of the data distribution center device 1
The broadcast data stored in No. 1 is extracted for each block, a block number, an error detection code, and a broadcast serial number are assigned, and the data block is transmitted through a broadcast line. Here, the data block (hereinafter, referred to as a block) is data obtained by dividing broadcast data into a size that is easy to transmit, and the block number is a sequential number assigned to this block in order from the beginning of the broadcast data. The broadcast serial number is a sequential number assigned in the order in which the blocks were transmitted. Therefore, a block can be uniquely specified by the block number, and at which time the block was broadcast can be uniquely specified by the broadcast serial number.

The broadcast data block receiving section 21 of the data receiving terminal device 21 receives the transmitted block and sends it to the reception error detecting section 22 together with the block number, the error detection code and the broadcast serial number. The reception error detection unit 22 checks the received data using the error detection code. If there is no error in the received data, the block is sent to the block data assembling unit 23 together with the block number. The block data assembling unit 23 assembles the data received in units of blocks using the block numbers and restores the broadcast data.

If there is an error in the received block, the reception error detector 22 notifies the stochastic retransmission request instructor 24 of the block number and the broadcast sequence number. The probabilistic retransmission request instructing unit 24 uses a probability so that retransmission requests are not temporarily concentrated when performing a retransmission request for an erroneous block so as to be dispersed to some extent.

When the stochastic retransmission request instructing unit 24 receives a notification that a transmission error has occurred from the reception error detecting unit 22, it requests retransmission according to the probability P. This probability P
Is calculated by P = α ^(AD) {α to the power of (AD)}. Here, α is a real number (0 <α <1), A is a predetermined integer (A ≧ 1), and D is the number of blocks received after receiving the notification of the transmission error. . When the transmission error is notified using the probability P, the retransmission request probability is set to the individual communication retransmission request unit 25 so that the retransmission request probability P is calculated using this formula. Instruct them to

That is, when the probability P = 0.1, 10
When transmission errors occur simultaneously in one data receiving terminal device, it means that only one of the ten receiving terminals issues a retransmission request. However, the probability P described above is
Each time a block is received, the value becomes large, and the probability P becomes “1” when the same number of blocks as the predetermined integer A is received. Therefore, a retransmission request is made at this time at the latest. If this integer A is set to a small value, retransmission requests can be made earlier, but retransmission requests tend to concentrate. If the integer A is set to a large value, concentration of retransmission requests can be prevented, but the timing at which retransmission requests are executed is delayed. Therefore, an integer A that allows a retransmission request to be performed efficiently can be determined from the number of receiving terminal devices constituting the data distribution system.

For example, when A = 5 and α = 0.1, when a certain block cannot be received, the value of D is increased by “1” each time each subsequent block is received. Therefore, P = 1/100000, 1/10000, 1/1000, 1/100, 1 /
An instruction for a retransmission request is issued with a probability of 10 or 1 sequence. This operation performed by the stochastic retransmission request instructing unit 24 is repeated until a retransmission request is issued at the probability. Since the last probability is “1”, the retransmission request processing for the block in which the error has been detected is completed at this time at the latest. When the retransmission request is issued, the difference D from the broadcast serial number is set to “0”. As described above, since the probability of making a retransmission request is set to the probability P, it is possible to prevent retransmission requests from concentrating on a plurality of data receiving terminal devices 2 at the same time even if a data error is detected.

When a data error has occurred in a plurality of adjacent blocks, if the probability for at least one of the blocks has been reached, an instruction is issued to request retransmission of all blocks having a data error at that time. It may be made to be.

The individual communication retransmission request unit 25 receives the instruction of the retransmission request from the stochastic retransmission request instruction unit 24, and sends the block number and the broadcast serial number to the individual data distribution center apparatus 1 via the communication line. The retransmission request receiving unit 14 is notified.

When the data receiving terminal device 2 requests retransmission of a certain block, it is necessary to make a retransmission request. Regardless of P, the retransmission request is piggybacked and the block number of the corresponding block is notified to the individual retransmission request receiving unit 14. The stochastic retransmission request instructing unit 24 terminates the retransmission request processing for issuing a retransmission request instruction based on the probability P for the block notified by piggybacking.

Next, the operation when a retransmission request is made will be described. The individual retransmission request reception unit 14 notifies the specific block retransmission unit 17 of all block numbers for which retransmission has been requested. At the same time, it notifies the retransmission request terminal size estimating unit 15 of the broadcast sequence number and the block numbers of the blocks included in the broadcast sequence number.

Next, the specific block retransmitting unit 17 reads the block of the block number notified from the individual retransmission request receiving unit 14 from the broadcast data storage unit 11 and transmits the individual communication data block of the data receiving terminal device 2 which has made the retransmission request. This is transmitted to the receiving unit 26. If a data transmission error occurs on the communication line during this transmission, the individual communication data block receiving unit 26 immediately sends a retransmission request to the specific block retransmitting unit 17 at that time, and
Reliably receive the block sent from. The received block is sent to the block data assembling unit 23 together with the block number, and the broadcast data is restored.

Next, the operation of estimating the number of retransmission requests and rebroadcasting the blocks requested to be retransmitted when the number is large will be described. Retransmission request terminal size estimation unit 1
5 counts the number C of retransmission requests notified from the individual retransmission request receiving unit 14 for each broadcast sequence number. Further, the difference between the broadcast sequence number notified of the retransmission request and the broadcast sequence number that has been broadcast at the current time is represented by D, and the aforementioned probability P
Is calculated in the same manner as the data receiving terminal device 2. The probability P may be directly received from the data receiving terminal as data.

Next, the number of terminals requesting block retransmission is estimated from the number C of retransmission requests and the probability P. The estimated number N of the data receiving terminal devices is N = (C / P) -C
(C: number of notifications, P: probability value). The estimated number N is an estimated value of the total number of data receiving terminals 2 that have not received a block through the communication line. Subsequently, the estimated number N is notified to the rebroadcasting determination unit 16 together with the broadcast sequence number and the block number included in the broadcast sequence number.

The rebroadcasting deciding section 16 calculates the estimated number N of the data receiving terminals 2 that are going to request retransmission of each block number.
However, if it exceeds a predetermined threshold value, it is determined that those blocks are to be rebroadcast, and the block number determined to be rebroadcasted is re-broadcasted to the rebroadcast advance broadcast unit 18 and the rebroadcast block interrupt processing. Notify the unit 13. This threshold value is determined from the contents of the broadcast data and the total number of data receiving terminals 2 so that retransmission by re-broadcasting using the broadcast line is more efficient than retransmission individually. Just do it.

The rebroadcast announcement broadcast unit 18 broadcasts a block number to be rebroadcast. Since the re-broadcast advance broadcast itself may cause a data error, the advance broadcast should be a broadcast to which an error correction code is added, a plurality of broadcasts, etc. I do.

The rebroadcast notice receiving unit 27 of the data receiving terminal device 2 notifies the stochastic retransmission request instructing unit 24 of the block number for which the rebroadcast is determined. Probabilistic retransmission request instructing unit 24
Terminates the retransmission request process for the block for which retransmission is determined among the blocks for which a retransmission request instruction is to be issued based on the probability P.

The rebroadcast block interrupt processing unit 13 interrupts the block notified from the retransmission broadcast determination unit 16 in the processing of the data block transmission unit 12 and transmits the block. At that time, an error detection code, a block number, and a new broadcast serial number are given. The rebroadcast block may cause a data error again. In that case, the same operation is repeated. In addition, since a request for retransmission of a block normally received without causing an error is no longer necessary, if a broadcast data error of a rebroadcast notice causes an error,
If the stochastic retransmission request instructing unit 24 has continued the process for the block, the process is terminated and terminated.

As described above, when the number of retransmission requests is small, data is transmitted individually, and when the number of retransmission requests is larger than the threshold value, rebroadcasting is performed, so that data is efficiently distributed. can do.

[0033]

As described above, according to the present invention, since the probability of making a retransmission request is set to the probability P, even if a data error is detected in a plurality of data receiving terminal devices at the same time, the retransmission request is not sent. The effect that concentration can be prevented can be obtained. According to the present invention, when a large number of terminals request retransmission of the same data block, the data block is quickly rebroadcasted, and when a small number of terminals request retransmission, the broadcast efficiency is reduced. Without retransmission, data can be retransmitted by individual communication, and the effect of efficiently performing data distribution while avoiding the explosion of retransmission requests can be obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing the number of terminal devices requesting retransmission when a data transmission error occurs on a route close to a data receiving terminal device.

FIG. 3 is an explanatory diagram showing the number of terminal devices requesting retransmission when a data transmission error occurs on a route close to a data distribution center device.

[Explanation of symbols]

1 ... Data distribution center device, 2 ... Data receiving terminal device. 11 ... broadcast data storage unit, 12 ... data block transmission unit, 13 ... rebroadcast block interrupt processing unit, 14 ... individual retransmission request reception unit, 15 ... retransmission request terminal size estimation unit, 16 ... Rebroadcast decision unit, 1
7 ... Specific block resending section, 18 ... Rebroadcast preview broadcasting section, 21 ... Broadcast data block receiving section, 22 ...
A reception error detector, 23 ... a block data assembler;
24: Stochastic retransmission request instructing unit, 25: individual communication retransmission requesting unit, 26: individual communication data block receiving unit, 27: rebroadcast notice receiving unit

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Goichi Maruyama 3-19-2 Nishi Shinjuku, Shinjuku-ku, Tokyo Nippon Telegraph and Telephone Corporation

Claims (5)

[Claims] 1. Broadcast data storing means for storing broadcast data to be broadcast, data block transmitting means for broadcasting the broadcast data to a data receiving terminal device in block units, and identification performed stochastically from the data receiving terminal device Individual retransmission request receiving means for receiving a block retransmission request by individual communication, specific block retransmission means for individually transmitting the specific block data for which retransmission has been requested to a data receiving terminal device, the number of retransmission requests for the specific block Retransmission requesting terminal size estimating means for estimating the total number of data receiving terminal devices requesting retransmission of the specific block; and a re-determining unit for determining whether to rebroadcast the data of the specific block based on the estimated total number of terminals. Broadcast determination means, and a rebroadcast preview broadcast for previewing information of the specific block determined to be rebroadcast And a re-broadcast block interrupt processing means for re-broadcasting the specific block determined to be re-broadcasted. 2. A broadcast data block receiving means for receiving broadcast data in block units, a reception error detecting means for checking whether or not the broadcast data has a reception error in block units; Probabilistic retransmission request instructing means for instructing a specific block that requires a retransmission request to start a retransmission request operation according to a probability value that increases with the progress of reception after the specific block, and retransmission for the specific block through a communication line. An individual communication retransmission request unit for notifying a request to the data distribution center device; an individual communication data block reception unit for receiving a specific block retransmitted by the individual communication retransmission request unit; and the broadcast data received in block units. Block data assembling means for assembling and restoring, and the specific block to be re-broadcasted A data reception terminal device, comprising: a rebroadcast notice receiving means for receiving information about 3. A data distribution system comprising the data distribution center device according to claim 1 and a plurality of data receiving terminal devices according to claim 2. 4. A retransmission requesting means of the data receiving apparatus, comprising the steps of:
And a predetermined integer A (A ≧ 1) and a real number α
Using (0 <α <1), a probability P = α ^(AD) is obtained, and an instruction to make a retransmission request is given by the probability P, so that retransmission requests are not temporarily concentrated. The data distribution system according to claim 3. 5. The terminal total number estimating means of the data distribution center device uses the number C of retransmission requests for a specific block and the probability P to calculate the total number N of data reception terminal devices that are to make a retransmission request by N. = (C / P) -C, this terminal total number N
5. The data distribution system according to claim 4, wherein when the value exceeds a predetermined threshold, the specific block is rebroadcast.