JP2013149102A - Broadcast distribution system, distribution server, terminal device, broadcast distribution method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a broadcast distribution system reducing loss of time and the amount of data caused by waiting of re-transmission of unreceived data by each terminal.SOLUTION: Each terminal 20 includes: a response data reception section 102 for receiving each block from a distribution server 10 and storing each block in storage means provided in advance; a request data generation section 203 for preparing request data requesting the distribution server 10 to transmit blocks which are not received yet in transmission object data; and a request data transmission section 204 for transmitting the prepared request data to the distribution server 10. The distribution server 10 includes: a request data reception section 102 for receiving the request data from each terminal 20; a transmission data control section 104 for determining which of blocks is transmitted to each terminal 20 on the basis of the received request data; and a data transmission section 101 for transmitting the determined block to each terminal 20.

Description

  The present invention relates to a broadcast distribution system, a distribution server, a terminal device, a broadcast distribution method, and a program, and more particularly, to a broadcast distribution system that can reduce loss of time and data amount related to data transmission.

  There are three main methods for transmitting data from one computer to another computer via a network, called unicast, multicast, and broadcast. Unicast when sending data to only one computer, multicast when sending the same data to multiple unspecified computers, and sending the same data to many unspecified computers This is called broadcasting.

  In the data transmission by the broadcast method, it is not necessary for the transmission source to specify the IP address of the transmission destination computer one by one. For example, the same data is addressed to an unspecified number of computers such as firmware and operating system updates. Suitable for cases where delivery is necessary.

  Further, regardless of the number of destination computers, the router on the transmission path copies the required number of data, so that only one data packet is transmitted from the transmission source. Therefore, there is an advantage that the burden on the network can be reduced.

  There are the following technical documents related to this. Among them, Patent Document 1 describes an update method in which firmware is divided into a plurality of blocks and transmitted by broadcast communication. Patent Document 2 describes an update method that suppresses the occurrence of missing blocks with firmware that is divided into a plurality of blocks and transmitted by broadcast communication.

  Patent Document 3 describes an update method in which firmware is transmitted and received as a package file. Patent Document 4 describes a download system in which firmware for a plurality of network devices is downloaded by a download tool connected to a network.

  Patent Document 5 describes a download system in which a program is distributed from a server to a plurality of mobile terminals by simultaneous broadcasting. Non-Patent Document 1 describes the differences between the above-described unicast, multicast, and broadcast transmission methods.

JP 2011-0666529 A JP2011-288026A Special table 2011-522302 gazette JP 2004-157733 A JP 2003-051796 A

Takashi Ashinoki, “Part 31“ Broadcast / Multicast / Unicast ”” (From “Takashi Ashinoki's BB WORDS”), March 28, 2005, Impress Corporation [Search December 28, 2011] , Internet <URL: http://bb.watch.impress.co.jp/cda/bbword/9021.html>

  As described above, data transmission by the broadcast method is often performed when it is necessary to deliver the same data to a large number of computers, such as firmware and operating system updates. However, not all terminals that receive the data are in an equivalent communication environment. For example, the line type, communication speed, and communication quality are all different. For this reason, a terminal that can normally receive the same data transmitted by the server and a terminal that fails to receive the data always appear.

  In addition, not all terminals that need the data can participate in receiving the data at the same timing. For example, there may be a case where the time for starting the reception of the data is delayed as compared with other computers due to, for example, taking time for other processing or when the power-on timing is different.

  In data transmission by the broadcast method, the server normally transmits the same data repeatedly repeatedly. Therefore, a terminal that has not received some data needs to wait until the same data is transmitted again from the server. This is a great loss both in terms of time and the amount of data to be transmitted.

  FIG. 10 is an explanatory diagram showing a configuration of a general broadcast distribution system 901. The broadcast distribution system 901 is configured by connecting a server 910 and an unspecified number of terminals 920 to each other via a network 930. The terminal 920 normally receives data transmitted repeatedly by the server 910. The terminal group 920A that has been received and the terminal group 920B that has not been received are divided.

  At this time, the terminals 920 belonging to the unreceived terminal group 920B cannot directly request unsent data from the server 910 for retransmission. This is because if the server 910 responds to such requests from all the terminals 920 one by one, the merit of the broadcast method is lost, and the burden on the network and the server 910 increases at a stretch. Eventually, the terminals 920 belonging to the terminal group 920B wait until the data is transmitted again from the server 910, and a great loss occurs.

  Techniques that can solve this problem are not described in the above-mentioned documents. A technique of dividing one program into a plurality of blocks and transmitting the same by broadcast communication is described in Patent Documents 1 and 2 and the like. However, with these technologies, each terminal requests the server to retransmit unreceived data, which increases the load on the network and server. This point is not solved by the techniques described in other documents.

  An object of the present invention is to provide a broadcast distribution system and distribution capable of reducing the loss of time and data amount caused by each terminal waiting for retransmission of unreceived data without increasing the burden on the network or server. A server, a terminal device, a broadcast distribution method, and a program are provided.

  In order to achieve the above object, a broadcast distribution system according to the present invention includes a single distribution server and an unspecified number of terminal devices connected to each other via a network, and the distribution server is divided into a plurality of blocks and stored in advance. A broadcast distribution system for transmitting the transmission target data to each terminal device by a broadcast method, wherein each terminal receives each block from the distribution server and stores it in a storage means provided in advance; When there is a block that has not been received yet in the transmission target data, a request data generation unit that generates request data for requesting the distribution server to transmit the unreceived block, and the generated request data are distributed And a data transmission unit that transmits to the server, and the distribution server receives request data from each terminal. A data receiving unit, a transmission data control unit for determining which block to transmit to each terminal based on the received request data, and a data transmitting unit for transmitting the determined block to each terminal And the transmission data control unit has a function of determining to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block.

  In order to achieve the above object, a distribution server according to the present invention is connected to an unspecified number of terminal devices via a network, and each of transmission target data divided into a plurality of blocks and stored in advance is broadcasted. A distribution server that transmits to a terminal device, each terminal receiving a request data requesting to transmit a block that has not yet been received in the data to be transmitted, and a data receiving unit based on the received request data A transmission data control unit that determines which block is to be transmitted to each terminal, and a data transmission unit that transmits the determined block to each terminal. It has a function of determining to transmit a block that is requested to be transmitted with request data from the largest number of terminals.

  In order to achieve the above object, a terminal apparatus according to the present invention is a terminal that is connected to each other via a network and a single distribution server that transmits data to be transmitted divided into a plurality of blocks and stored in advance by a broadcast method. If there is a data receiving unit that receives each block from the distribution server and stores it in a storage means provided in advance and a block that has not yet been received in the transmission target data, the unreceived block A request data generation unit that generates request data for requesting the distribution server to transmit the message, and a data transmission unit that transmits the generated request data to the distribution server.

  In order to achieve the above object, according to the broadcast distribution method of the present invention, a single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks and stored in advance. In the broadcast distribution system that transmits the transmitted transmission target data to each terminal device by the broadcast method, when the request data creation unit of each terminal includes a block that has not yet been received in the transmission target data, Create request data to request the distribution server to transmit the unreceived block, the data transmission unit of each terminal transmits the generated request data to the distribution server, and the data reception unit of the distribution server The transmission data control unit of the distribution server receives the request data from each block based on the received request data. A decision is made to send to each terminal the block requested to be transmitted with the request data from the most terminals, and the data transmission unit of the distribution server sends the determined block to each terminal. The data reception unit of the terminal receives each block from the distribution server and stores it in a storage means provided in advance.

  In order to achieve the above object, a broadcast distribution program according to the present invention includes a single distribution server and an unspecified number of terminal devices connected to each other via a network, and the distribution server is divided into a plurality of blocks and stored in advance. In a broadcast distribution system for transmitting the transmission target data to each terminal device by the broadcast method, each terminal transmits a block that has not yet been received in the transmission target data to a computer provided in the distribution server. A procedure for receiving requested request data, and a procedure for deciding to transmit to each terminal a block that is requested to be transmitted with request data from the largest number of terminals in each block based on the received request data And a procedure for transmitting the determined block to each terminal. To.

  In order to achieve the above object, another broadcast distribution program according to the present invention includes a single distribution server and an unspecified number of terminal devices connected to each other via a network, and the distribution server is divided into a plurality of blocks. In a broadcast distribution system that transmits pre-stored transmission target data to each terminal device by a broadcast method, when there is a block that has not yet been received in the transmission target data in a computer provided in each terminal, A procedure for creating request data for requesting the distribution server to transmit the unreceived block, a procedure for transmitting the created request data to the distribution server, and a storage means provided in advance for receiving each block from the distribution server It is characterized in that the procedure stored in the is executed.

  As described above, the present invention is configured so that each terminal requests a block that the terminal wants to receive from the distribution server, and the distribution server determines a block to be transmitted by majority vote based on the request from each terminal. The block to be transmitted can be appropriately selected and transmitted without losing the merit of the broadcast method that does not increase the burden on the server.

  This makes it possible to reduce the time and data loss caused by each terminal waiting for retransmission of unreceived data without increasing the load on the network or server. A system, a distribution server, a terminal device, a broadcast distribution method, and a program can be provided.

It is explanatory drawing which shows the structure of the broadcast delivery system which concerns on the 1st Embodiment of this invention. It is explanatory drawing shown about the structure of the transmission object data memorize | stored in the transmission data storage part of the server shown in FIG. It is a flowchart shown about operation | movement between the server shown in FIG. 1, and a terminal. FIG. 4 is a block diagram showing in more detail the operation of determining “which block to transmit next” by the transmission data control unit shown as step S305 in FIG. 3. It is explanatory drawing shown about the example of operation | movement between the server shown in FIGS. It is explanatory drawing shown about the example of another operation | movement between the server shown in FIGS. 3-4, and a terminal. It is explanatory drawing which shows the structure of the broadcast delivery system which concerns on the 2nd Embodiment of this invention. It is a flowchart shown about operation | movement between the server shown in FIG. 7, and a terminal. FIG. 9 is an explanatory diagram illustrating an operation of transmitting the block divided and divided into two blocks by the operation shown as step S807 in FIG. 8. It is explanatory drawing which shows the structure of the general broadcast delivery system 901.

(First embodiment)
Hereinafter, the configuration of an embodiment of the present invention will be described with reference to FIG.
First, the basic content of the present embodiment will be described, and then more specific content will be described.
In the broadcast distribution system 1 according to the present embodiment, a single distribution server (server 10) and an unspecified number of terminal devices (terminals 20) are connected to each other via a network, and the distribution server is divided into a plurality of blocks. The broadcast distribution system transmits the transmission target data stored in advance to each terminal device by the broadcast method. Each terminal 20 receives each block from the distribution server and stores it in a storage means provided in advance, and when there is a block that has not been received yet in the transmission target data, A request data generation unit 203 that generates request data for requesting the distribution server to transmit a block, and a request data transmission unit 204 that transmits the generated request data to the distribution server. The distribution server 10 also includes a request data receiving unit 102 that receives request data from each terminal, and a transmission data control unit 104 that determines which block to transmit to each terminal based on the received request data. The data transmission unit 101 transmits the determined block to each terminal. The transmission data control unit 104 has a function of deciding to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block.

  In addition, if there is a terminal that has all the transmission target data if the remaining one block is received, the transmission data control unit 104 of the distribution server 10 transmits the block that is requested to be transmitted with the request data from the terminal. It has a function to determine as follows. Further, the transmission data control unit 104 of the distribution server 10 has a function of stopping transmission of transmission target data when request data from the terminal is not received.

By providing the above configuration, the broadcast distribution system 1 according to the present embodiment causes a loss of time and data amount caused by each terminal waiting for retransmission of unreceived data without increasing the burden on the network or server. Can be reduced.
Hereinafter, this will be described in more detail.

  FIG. 1 is an explanatory diagram showing a configuration of a broadcast distribution system 1 according to the first embodiment of the present invention. The broadcast distribution system 1 is configured by connecting a server 10 and an unspecified number of terminals 20 to each other via a network 30. The server 10 may be a single computer device or a plurality of computer devices.

  The terminal 20 is an unspecified number of computer devices, all of which are trying to receive the same data from the server 10. For reasons of space, FIG. 1 shows only one server 10 and three terminals 20.

  The server 10 has a basic configuration as a computer device. That is, the processor 11 that is the operation subject of the computer program, the storage unit 12 that stores the program and data, the communication unit 13 that communicates with other devices via the network 30, and the network administrator performs operation input. Input means 14.

  The processor 11 functions as a data transmission unit 101, a request data reception unit 102, a request data analysis unit 103, and a transmission data control unit 104 by operating the broadcast distribution program. In the storage unit 12, a transmission data storage unit 111 is secured as a storage area.

  The terminal 20 also has a basic configuration as a computer device. That is, the computer 21 includes a processor 21 that is an operation subject of the computer program, a storage unit 22 that stores the program and data, and a communication unit 23 that communicates with other devices via the network 30.

  The processor 21 functions as a data reception unit 201, a reception data control unit 202, a request data generation unit 203, and a request data transmission unit 204 by operating the broadcast reception program. The storage means 22 has a received data storage unit 211 as a storage area.

  FIG. 2 is an explanatory diagram showing the configuration of the transmission target data 120 stored in the transmission data storage unit 111 of the server 10 shown in FIG. The transmission target data 120 is divided into 10 blocks 120 a to j and stored in the transmission data storage unit 111. In the broadcast distribution system 1, the transmission target data 120 is data that each terminal 20 is about to receive.

  In this example, it is assumed that the transmission target data 120 is firmware update data of each terminal 20, but may be, for example, operating system or application software update data.

  In the example shown in FIG. 2, the transmission target data 120 is divided into 10 data blocks (hereinafter simply referred to as blocks). The transmission data control unit 104 sets the size per block for this division number. Can be determined dynamically. Here, in order to simplify the description, it is merely divided into 10 blocks.

  FIG. 3 is a flowchart showing an operation between the server 10 and the terminal 20 shown in FIG. Although FIG. 3 also shows one each of the server 10 and the terminal 20, the server 10 actually performs the same operation on all the terminals 20.

  First, the system administrator operates the input unit 14 on the server 10 side, stores the transmission target data 120 in the transmission data storage unit 111, sets the size per block, and divides the data into blocks 120a to 120j. (Step S301) When the broadcast transmission start is instructed, the data transmission unit 101 first starts transmission of the block 120a (Step S302). In the normal technique, the block 120a is followed by a block 120b, then a block 120c, and so on. The determination of the transmission order in this embodiment will be described later.

  In the terminal 20 that has received the data from the server 10 (step S351), the data receiving unit 201 stores the received block in the received data storage unit 211 (step S352). Then, the reception data control unit 202 determines whether or not the data of all the blocks is ready (step S353). Here, the criterion for determining whether or not the data of all the blocks is complete is the total capacity of the transmission target data 120 declared in the data header given when the data transmission unit 101 transmits each block, For example, the total number of blocks and the data size per block.

  If it is determined in step S353 that all the blocks of data have been prepared, the firmware of the terminal 20 is updated using all the data (step S356), and the process is terminated. If it is determined that the data of all the blocks is not complete, the request data generation unit 203 creates data for requesting the server 10 to transmit the insufficient data (step S354), and the request data is used as the request data. The transmission unit 204 transmits to the server 10 (step S355), and the processing on the terminal 20 side returns to step S351 and waits for reception of the next block.

  Upon receiving the request data, the server 10 determines whether or not the request data receiving unit 102 has received the request data (step S303). If received, the request data analyzing unit 103 analyzes the content of the request data. Which terminal 20 is requesting which block is analyzed (step S304), and based on this, the transmission data control unit 104 determines which block is to be transmitted next (step S305, details will be described later in FIG. 4). ).

  Then, the control returns to step S302 described above, and the data transmission unit 101 transmits the block determined in step S305. Thereafter, this operation is repeated. If the request data is not received from any terminal 20 in step S303, it means that all the terminals 20 have received the transmission target data 120. Therefore, the request data receiving unit 102 stores the transmission target data 120 by the server 10. End transmission.

  FIG. 4 is a block diagram illustrating in more detail the operation of determining “which block to transmit next” by the transmission data control unit 104, which is shown as step S305 in FIG. The transmission data control unit 104 takes statistics of request data from each terminal 20 accessing the server 10 and calculates the data block requested from the largest number of terminals 20, thereby determining the priority of the data block to be distributed. Control.

  The transmission data control unit 104 collects statistics on the request data received from each terminal 20, and determines the transmission priority of each block in the order requested from the largest number of terminals (step S401). Then, it is determined whether or not there is a terminal with the number of remaining blocks = 1 in each terminal 20 (step S402), and if there is not, the process proceeds to step S405 described later. In order to determine whether or not there is a terminal having the number of remaining blocks = 1, an ARP response that is sent back to the server 10 when each terminal 20 has successfully received each block is recorded and received for each terminal 20. You may make it memorize | store a completed block. Alternatively, each terminal 20 may transmit the request data including the remaining number of blocks.

  If there is a terminal with the number of remaining blocks = 1 in step S402, the most requested block from the terminal with the remaining number of blocks = 1 and a block scheduled to be transmitted next from the server 10 (transmission priority is highest). Is matched (step S403). If they match, the process proceeds to step S405 described later. If they do not match, the transmission priority of the block most requested from the terminal with the number of remaining blocks = 1 is determined as the highest (step S404), and the process proceeds to step S405 described later. As a result, when there is a terminal having the number of remaining blocks = 1, it is possible to prompt the terminal to update preferentially.

  Then, the transmission data control unit 104 causes the data transmission unit 101 to transmit the block having the highest transmission priority (step S405). Thus, the operation of the transmission data control unit 104 shown as step S305 in FIG. 3 ends.

  FIG. 5 is an explanatory diagram showing an example of the operation between the server 10 and the terminal 20 shown in FIGS. In this example, the transmission target data 120 transmitted from the server 10 to each terminal 20 is divided into 10 blocks 120a to j (A to J) as shown in FIG. The three terminals 20a, 20b, and 20c are about to receive the transmission target data 120. Originally, a large number of unspecified numbers of terminals 20 are connected to the server 10, but only three terminals 20a to 20c are shown here for simplicity of the concept of the present invention.

  In broadcast communication, the server 10 repeatedly transmits the data of each block 120a-j (A-J) in order. The terminals 20a and 20b access the server 10 at the same timing and receive the transmission target data 120, but the terminal 20c starts receiving the transmission target data 120 compared to the other terminals 20a and 20b. Is different.

  Therefore, the terminals 20a and 20b have successfully received the four blocks 120a, 120b, 120c, and 120d (A, B, C, and D), but the terminal 20c has the blocks 120a and 120b (A, B) and the blocks. Reception of four blocks 120i and 120j (I, J) has been completed normally. That is, since the timing at which reception of the transmission target data 120 is started is different, a situation has occurred in which the blocks received by each terminal are not uniform.

  Here, the terminals 20a and 20b request the block 120e (E), and the terminal 20c requests 120c (C) as the data to be received next in the request data in steps S354 to 355. The server 10 that has received the request data from these terminals 20a to 20c in the operations of steps S303 to 304 determines the next block to be transmitted in the operation of step S305 (FIG. 4).

  In this example, there is no terminal with the number of remaining blocks = 1, two terminals requesting the block 120e (E), and one terminal requesting the block 120c (C). Therefore, the block 120e (E ) Is determined as a block to be transmitted next, and the data transmission unit 101 transmits the block.

  As a result, the terminals 20a and 20b have completed receiving the blocks 120a, 120b, 120c, 120d, and 120e (A, B, C, D, and E). Terminal 20c has completed receiving blocks 120a, 120b, 120e, 120i, and 120j (A, B, E, I, J). Then, the terminals 20a and 20b request the block 120f (F), and the terminal 20c requests 120c (C) as data to be received next. In response to this, the server 10 transmits the block 120f. Thereafter, the same operation is repeated until all of the terminals 20a to 20c have received all of the transmission target data 120 (blocks 120a to j).

  FIG. 6 is an explanatory diagram showing another example of the operation between the server 10 and the terminal 20 shown in FIGS. Similar to FIG. 5, the transmission target data 120 is divided into 10 blocks 120a to 120j, and the three terminals 20a, 20b, and 20c are about to receive the transmission target data 120. Among them, only the terminal 20a has completed reception of nine blocks 120a to i (A to I), and the terminals 20b and 20c have completed reception of eight blocks 120a to h (A to H). Stays on.

  Here, the terminal 20a requests the block 120j (J), and the terminals 20b and 20c request 120i (I) as the data to be received next. In the server 10 that has received the request data from these terminals 20a to 20c, since only the terminal 20a has the number of remaining blocks = 1, one terminal that requests the block 120j (J) requests one block 120i (I). Although there are two terminals, the block 120j (J) is preferentially transmitted here. As a result, the terminal 20a has all of the blocks 120a to 120j (transmission target data 120), and can preferentially update the firmware.

(Overall operation of the first embodiment)
Next, the overall operation of the above embodiment will be described.
In the broadcast distribution method according to this embodiment, a single distribution server 10 and an unspecified number of terminal devices 20 are connected to each other via a network, and the distribution server is divided into a plurality of blocks and stored in advance. In the broadcast distribution system 1 that transmits data to each terminal device by the broadcast method, when there is a block that the request data creation unit of each terminal has not yet received in the transmission target data, the data is not received Request data for requesting the distribution server to transmit the block (FIG. 3, step S354), and the request data transmission unit of each terminal transmits the generated request data to the distribution server (FIG. 3, step S355). ), The request data receiving unit of the distribution server receives the request data from each terminal (FIG. 3, step S303), Based on the received request data, the transmission data control unit of the trust server determines to transmit to each terminal the block that is requested to be transmitted with the request data from the largest number of terminals in each block ( 3 and steps S304 to 305), the data transmission unit of the distribution server transmits the determined block to each terminal (FIG. 3, step S302), and the data reception unit of each terminal receives each block from the distribution server. Is stored in a storage means provided in advance (FIG. 3, steps S351 to 352).

Here, each of the above-described operation steps may be programmed to be executable by a computer, and these may be executed by the distribution server 10 and the processors 11 and 21 of the terminal 20 that directly execute the respective steps. The program may be recorded on a non-temporary recording medium, such as a DVD, a CD, or a flash memory. In this case, the program is read from the recording medium by a computer and executed.
By this operation, this embodiment has the following effects.

  According to this embodiment, the server determines a block to be transmitted by majority vote based on request data from each terminal. As a result, the server can select and transmit a more appropriate block, and it is possible to reduce the loss of time and data amount caused by each terminal waiting for retransmission of unreceived data.

  In particular, since the “remaining one block” is preferentially transmitted to a terminal that receives all the data to be transmitted if one more block is received, it can be used more frequently in applications such as firmware updates. It is possible to update the firmware for the terminal.

  This increases the burden on the network and server only for the requested data. Even in data transmission by a normal broadcast method, each terminal transmits a response packet such as an ARP response to the server, so this does not increase the load on the network or the server. Therefore, the merit of the broadcast method is not impaired, and the burden on the network and the server is not inadvertently increased.

(Second Embodiment)
The broadcast distribution system 501 according to the second embodiment of the present invention uses the request data generation unit 703 of each terminal 520 as a request data including a block that requests transmission and a request count that is the number of times the block has been requested to transmit. In addition to having a function to include, the distribution server 510 includes a block division combining unit 605 that divides the block into smaller capacities when the number of requests is 2 or more, and the transmission data control unit 604 includes the divided blocks. Send to the data transmitter. Further, when the transmission data control unit 604 of the distribution server 510 obtains a response indicating that the divided blocks have been normally received from the terminal, the blocks divided by the block division combining unit are combined together.

With this configuration, in addition to the same effects as those of the first embodiment, it is possible to improve the success rate of transmission / reception by further dividing the block into smaller capacities.
Hereinafter, this will be described in more detail.

  FIG. 7 is an explanatory diagram showing a configuration of a broadcast distribution system 501 according to the second embodiment of the present invention. The broadcast distribution system 501 includes a server 510 and a terminal 520 that are different from those in the first embodiment and are connected to each other via the same network 30 as that in the first embodiment. As in FIG. 1, only one server 510 and three terminals 520 are shown in FIG.

  The server 510 and the terminal 520 have the same configuration as the server 10 and the terminal 20 of the first embodiment as hardware. Also, the software is only partially different, and most is the same as the first embodiment. Therefore, elements that are the same as in the first embodiment are referred to by the same designations and reference numbers.

  In each functional unit operating on the processor 11 of the server 510, the data transmission unit 101 and the request data reception unit 102 are the same as those in the first embodiment, and the data analysis unit 603 and the transmission data control unit 604 are in the first embodiment. And different. In addition, a block division coupling unit 605 is newly added.

  As for each functional unit operating on the processor 21 of the terminal 520, the data receiving unit 201, the received data control unit 202, and the request data transmitting unit 204 are the same as those in the first embodiment, and the request data generating unit 703 is the first one. Different from the embodiment. Except for the above points, the second embodiment is the same as the first embodiment.

  FIG. 8 is a flowchart showing an operation between the server 510 and the terminal 520 shown in FIG. Again, the same processing as the operation of the first embodiment shown in FIG. In the operation in the server 510, steps S301 to S305 are the same as those in the first embodiment. Similarly, the operation in the terminal 520 is the same as that of the first embodiment in steps S351 to S353.

  In the terminal 520, the request data generation unit 703 not only receives the next block number to be received as the request data to be transmitted to the server 510, but also the number of remaining blocks that need to be received to configure the transmission target data 120, and Request data including the number of requests indicating the number of reception requests for the block is generated (step S854), and the request data is transmitted to the request data transmission unit 204 and transmitted to the server 510 (step S855).

  In the server 510 that has received this, the data analysis unit 603 analyzes the number of remaining blocks and the number of requests included in the request data and passes them to the transmission data control unit 604 (step S3045). Receiving this, the transmission data control unit 604 determines the next block to be transmitted in the same manner as in the first embodiment (step S305). Then, whether or not the block to be transmitted next is the request data received from the terminal 520 and the number of requests is ≧ 2, that is, whether or not the block is “the terminal 520 fails to receive and requests retransmission”. Is determined (step S806). If the number of requests = 1, the block is transmitted to the data transmission unit 101 as in the first embodiment.

  If the number of requests is greater than or equal to 2 in step S806, the block division combining unit 605 divides the block into two blocks, and transmits this to the data transmission unit 101 (step S807). This makes it possible to increase the probability of successful reception on the terminal 520 side. Then, after dividing and transmitting, it is checked whether or not a successful reception has been returned from the terminal 520 (step S808), and if unsuccessful, the process returns to step S807 to repeat retransmission of the block. If successful, the block division combining unit 605 combines the divided blocks again (step S809) and continues the original processing. Incidentally, the “successful reception” in step S808 may be a normal response packet such as an ARP response.

  FIG. 9 is an explanatory diagram showing the operation of the block dividing / combining unit 605 dividing the block into two blocks and transmitting the operation shown as step S807 in FIG. In the example shown in FIG. 9, the block 120e (E) is divided into two blocks “E1 and E2” and transmitted to the data transmitting unit 101.

  In step S806, the request count may be determined to be “3 or more” instead of “2 or more”, or another condition may be a retransmission request, and the block division combining unit 605 may determine that the block is three or more blocks. Alternatively, if the block repeatedly fails to transmit and receive, the block may be further finely divided. Furthermore, it is not necessary to divide into equal capacity blocks.

  Although the present invention has been described with reference to the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and any known ones can be used as long as the effects of the present invention are exhibited. Even if it is a structure, it is employable.

  Regarding the embodiment described above, the main points of the new technical contents are summarized as follows. In addition, although a part or all of the said embodiment is put together as follows as a novel technique, this invention is not necessarily limited to this.

(Supplementary Note 1) A single distribution server and a large number of unspecified terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks, and the transmission target data stored in advance is transmitted by the broadcast method. A broadcast distribution system for transmitting to a terminal device,
Each terminal is
If there is a data receiving unit that receives each block from the distribution server and stores it in a storage means provided in advance, and the block that has not yet been received in the transmission target data, the unreceived block is A request data generation unit that generates request data to request the distribution server to transmit, and a request data transmission unit that transmits the generated request data to the distribution server;
The distribution server is
A request data receiving unit that receives the request data from each terminal, and a transmission data control unit that determines which block to transmit to each terminal based on the received request data. A data transmission unit for transmitting the block to each terminal,
The transmission data control unit is
A broadcast distribution system having a function of deciding to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block.

(Supplementary Note 2) The transmission data control unit of the distribution server is
When there is the terminal that has all the transmission target data if the remaining one block is received, it has a function of determining to transmit a block that is requested to be transmitted by request data from the terminal. The broadcast distribution system according to attachment 1.

(Supplementary Note 3) The transmission data control unit of the distribution server is
The broadcast distribution system according to appendix 1, wherein the broadcast distribution system has a function of stopping transmission of the transmission target data when the request data from the terminal is not received.

(Supplementary Note 4) The request data generation unit of each terminal is
The request data includes a block that requests transmission and a request count that is the number of times the block is requested to be transmitted.
The distribution server is
A block division coupling unit that divides the block into smaller capacities when the number of requests is 2 or more;
The broadcast distribution system according to appendix 1, wherein the transmission data control unit causes the data transmission unit to transmit the divided blocks.

(Additional remark 5) When the said transmission data control part of the said delivery server gets the response to the effect that the said divided | segmented block was received normally from the said terminal, the said division | segmentation block is made to the said block division | segmentation coupling | bond part. The broadcast distribution system according to appendix 4, wherein the broadcast distribution system is combined as before.

(Supplementary Note 6) A distribution server which is connected to a large number of unspecified terminal devices via a network and transmits transmission target data divided into a plurality of blocks and stored in advance to each terminal device by a broadcast method. There,
A data receiving unit that receives request data requesting that each terminal transmit the block that has not yet been received in the transmission target data;
A transmission data control unit that determines which block to transmit to each terminal based on the received request data;
A data transmission unit that transmits the determined block to each terminal;
The transmission data control unit is
A distribution server having a function of deciding to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block.

(Supplementary note 7) A terminal device connected to each other via a network and a single distribution server that transmits transmission target data divided into a plurality of blocks and stored in advance by a broadcast method,
A data receiving unit that receives the respective blocks from the distribution server and stores them in a storage unit provided in advance;
A request data generation unit that creates request data for requesting the distribution server to transmit the unreceived block when there is the block that has not yet been received in the transmission target data;
A terminal device comprising: a data transmission unit configured to transmit the created request data to the distribution server.

(Supplementary Note 8) A single distribution server and a large number of unspecified terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks, and the transmission target data stored in advance is transmitted by the broadcast method. In a broadcast distribution system that transmits to a terminal device,
The request data creation unit of each terminal creates request data for requesting the distribution server to transmit the unreceived block when there is the block not yet received in the transmission target data,
The request data transmission unit of each terminal transmits the created request data to the distribution server,
A request data receiving unit of the distribution server receives the request data from each terminal;
Based on the received request data, the transmission data control unit of the distribution server transmits a block that is requested to be transmitted with the request data from the largest number of terminals among the blocks to the terminals. Decided to
The data transmission unit of the distribution server transmits the determined block to each terminal,
A broadcast distribution method, wherein a data receiving unit of each terminal receives each block from the distribution server and stores the block in a storage unit provided in advance.

(Supplementary Note 9) A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks, and the transmission target data stored in advance is transmitted by the broadcast method. In a broadcast distribution system that transmits to a terminal device,
In the computer provided in the distribution server,
A procedure for receiving request data requesting that each terminal transmit the block that has not yet been received in the transmission target data;
A procedure for determining, based on the received request data, to transmit to each terminal a block that is requested to be transmitted with request data from the largest number of terminals in each block;
And a broadcast delivery program for causing the determined block to be transmitted to each terminal.

(Supplementary Note 10) A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks, and the transmission target data stored in advance is transmitted by the broadcast method. In a broadcast distribution system that transmits to a terminal device,
In the computer provided in each terminal,
A procedure for creating request data for requesting the distribution server to transmit an unreceived block when there is the block not yet received in the transmission target data;
A procedure for transmitting the created request data to the distribution server;
And a broadcast distribution program for executing a procedure of receiving each block from the distribution server and storing the blocks in a storage means provided in advance.

  The present invention is applicable to a system that performs data transmission by a broadcast method. It is particularly suitable for applications such as firmware and operating system updates.

DESCRIPTION OF SYMBOLS 1,501 Broadcast delivery system 10,510 Server 11,21 Processor 12,22 Storage means 13,23 Communication means 14 Input means 20,20a-c, 520,520a-c Terminal 30 Network 101 Data transmission part 102 Request data reception part 103, 603 Request data analysis unit 104, 604 Transmission data control unit 111 Transmission data storage unit 120 Transmission target data 120a-j Block 201 Data reception unit 202 Reception data control unit 203, 703 Request data generation unit 204 Request data transmission unit 211 Reception Data storage unit 605 Block division coupling unit

Claims (10)

A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks and prestored transmission target data is broadcast to each terminal device. A broadcast distribution system for transmitting
Each terminal is
If there is a data receiving unit that receives each block from the distribution server and stores it in a storage means provided in advance, and the block that has not yet been received in the transmission target data, the unreceived block is A request data generation unit that generates request data to request the distribution server to transmit, and a request data transmission unit that transmits the generated request data to the distribution server;
The distribution server is
A request data receiving unit that receives the request data from each terminal, and a transmission data control unit that determines which block to transmit to each terminal based on the received request data. A data transmission unit for transmitting the block to each terminal,
The transmission data control unit is
A broadcast distribution system having a function of deciding to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block. The transmission data control unit of the distribution server,
When there is the terminal that has all the transmission target data if the remaining one block is received, it has a function of determining to transmit a block that is requested to be transmitted by request data from the terminal. The broadcast distribution system according to claim 1. The transmission data control unit of the distribution server,
The broadcast distribution system according to claim 1, further comprising a function of stopping transmission of the transmission target data when the request data from the terminal is not received. The request data generation unit of each terminal is
The request data includes a block that requests transmission and a request count that is the number of times the block is requested to be transmitted.
The distribution server is
A block division coupling unit that divides the block into smaller capacities when the number of requests is 2 or more;
The broadcast distribution system according to claim 1, wherein the transmission data control unit causes the data transmission unit to transmit the divided blocks.   When the transmission data control unit of the distribution server obtains a response from the terminal that the divided block has been normally received, the block division combining unit restores the divided block to the original state. The broadcast delivery system according to claim 4, wherein A distribution server connected to an unspecified number of terminal devices via a network and transmitting transmission target data divided into a plurality of blocks and stored in advance to each terminal device by a broadcast method,
A request data receiving unit that receives request data requesting that each terminal transmit the block that has not yet been received in the transmission target data;
A transmission data control unit that determines which block to transmit to each terminal based on the received request data;
A data transmission unit that transmits the determined block to each terminal;
The transmission data control unit is
A distribution server having a function of deciding to transmit a block that is requested to be transmitted with request data from the largest number of terminals in each block. A terminal device connected to each other via a network and a single distribution server that transmits the transmission target data divided into a plurality of blocks and stored in advance by a broadcast method,
A data receiving unit that receives the respective blocks from the distribution server and stores them in a storage unit provided in advance;
A request data generation unit that creates request data for requesting the distribution server to transmit the unreceived block when there is the block that has not yet been received in the transmission target data;
A terminal device, comprising: a request data transmission unit configured to transmit the created request data to the distribution server. A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks and prestored transmission target data is broadcast to each terminal device. Broadcast distribution system that sends
The request data creation unit of each terminal creates request data for requesting the distribution server to transmit the unreceived block when there is the block not yet received in the transmission target data,
The request data transmission unit of each terminal transmits the created request data to the distribution server,
A request data receiving unit of the distribution server receives the request data from each terminal;
Based on the received request data, the transmission data control unit of the distribution server transmits a block that is requested to be transmitted with the request data from the largest number of terminals among the blocks to the terminals. Decided to
The data transmission unit of the distribution server transmits the determined block to each terminal,
A broadcast distribution method, wherein a data receiving unit of each terminal receives each block from the distribution server and stores the block in a storage unit provided in advance. A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks and prestored transmission target data is broadcast to each terminal device. Broadcast distribution system that sends
In the computer provided in the distribution server,
A procedure for receiving request data requesting that each terminal transmit the block that has not yet been received in the transmission target data;
A procedure for determining, based on the received request data, to transmit to each terminal a block that is requested to be transmitted with request data from the largest number of terminals in each block;
And a broadcast delivery program for causing the determined block to be transmitted to each terminal. A single distribution server and an unspecified number of terminal devices are connected to each other via a network, and the distribution server is divided into a plurality of blocks and prestored transmission target data is broadcast to each terminal device. Broadcast distribution system that sends
In the computer provided in each terminal,
A procedure for creating request data for requesting the distribution server to transmit an unreceived block when there is the block not yet received in the transmission target data;
A procedure for transmitting the created request data to the distribution server;
And a broadcast distribution program for executing a procedure of receiving each block from the distribution server and storing the blocks in a storage means provided in advance.

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