JP2015177505A - Transmission device, communication system, data transmission method and data transmission program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress an excessive communication load caused by parallel transmission of data by effectively utilizing a plurality of communication paths.SOLUTION: On the basis of an allowable band that is a bandwidth capable of performing data transmission in each of a plurality of communication paths connected in parallel with a receiving device, a transmission device sets a transmission band that is a bandwidth for transmitting a predetermined data group to the receiving device, for each of the plurality of communication paths and on the basis of the transmission band that is set for each of the plurality of communication paths, the transmission device transmits the same predetermined data group in parallel to the plurality of communication paths.

Description

  The present invention relates to a transmission apparatus, a communication system, a data transmission method, and a data transmission program, and in particular, a transmission apparatus, a communication system, a data transmission method, and a data transmission program that transmit data to a reception apparatus using a plurality of communication paths. The present invention relates to a data transmission program.

  When data is transmitted from the transmission source to the reception destination, a plurality of communication paths may be used to reliably transmit the data. For example, Patent Document 1 discloses a technique related to a communication system including a master station and a plurality of terminal stations and having two or more communication paths. In particular, in Patent Document 1, when the same data is transmitted to the terminal station through a plurality of different routes from the master station, the received data received first at the terminal station is output to the terminal device, etc. There is a description that data received later is invalid.

Japanese Patent Laid-Open No. 10-242922

  However, as in Patent Document 1, when the same data is transmitted all at once to a plurality of communication paths, there is a problem that the communication load of the entire network increases. In particular, when a plurality of communication paths are not dedicated lines, an excessive communication load may be applied to each communication path due to the influence of other communication.

  The present invention has been made to solve such problems, and a transmitter and a communication system for suppressing an excessive communication load due to parallel transmission of data by effectively using a plurality of communication paths. An object of the present invention is to provide a data transmission method and a data transmission program.

The transmission device according to the first aspect of the present invention is:
A bandwidth for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel with the receiving device. Set a transmission band for each of the plurality of communication paths,
Based on the transmission bandwidth set for each of the plurality of communication paths, the same predetermined data group is transmitted in parallel to each of the plurality of communication paths.

A communication system according to the second aspect of the present invention includes:
A transmission device and a reception device connected to the transmission device by a plurality of parallel communication paths;
The transmitter is
A transmission band that is a bandwidth for transmitting a predetermined data group toward the receiving device is set for each of the plurality of communication paths based on an allowable band that is a bandwidth capable of data transmission in each of the plurality of communication paths. Set,
Based on the transmission bandwidth set for each of the plurality of communication paths, the same predetermined data group is transmitted in parallel to each of the plurality of communication paths.

A data transmission method according to the third aspect of the present invention includes:
A band for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel between the transmitting device and the receiving device. A transmission band that is a width is set for each of the plurality of communication paths,
Based on the transmission band set for each of the plurality of communication paths, the same predetermined data group is transmitted in parallel from the transmission apparatus to each of the plurality of communication paths.

A data transmission program according to the fourth aspect of the present invention includes:
A bandwidth for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel with the receiving device. A process of setting a transmission band for each of the plurality of communication paths;
A process of transmitting the same predetermined data group in parallel to each of the plurality of communication paths, based on the transmission band set for each of the plurality of communication paths;
Is executed on the computer.

  According to the present invention, it is possible to provide a transmission device, a communication system, a data transmission method, and a data transmission program for suppressing an excessive communication load due to parallel transmission of data by effectively using a plurality of communication paths. .

1 is a block diagram showing an overall configuration of a communication system according to a first exemplary embodiment of the present invention. It is a flowchart which shows the flow of the data transmission process concerning Embodiment 1 of this invention. It is a block diagram which shows the structure of the communication system concerning Embodiment 2 of this invention. It is a sequence diagram which shows the flow of the data transmission process concerning Embodiment 2 of this invention. It is a figure for demonstrating the concept of the communication system concerning Embodiment 3 of this invention. It is a flowchart which shows the flow of the data transmission process in the transmitter concerning Embodiment 3 of this invention. It is a flowchart which shows the flow of the data reception process in the receiver concerning Embodiment 3 of this invention. It is a block diagram which shows the structure of the communication system concerning Embodiment 4 of this invention. It is a figure for demonstrating the concept of the communication system concerning Embodiment 4 of this invention.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. In the drawings, the same elements are denoted by the same reference numerals, and redundant description will be omitted as necessary for the sake of clarity.

<Embodiment 1 of the Invention>
FIG. 1 is a block diagram showing an overall configuration of a communication system 1 according to the first exemplary embodiment of the present invention. The communication system 1 includes a transmission device 10, a reception device 20, and communication paths 31, 32, ..., and 3n (n is a natural number of 2 or more). The communication paths 31 to 3n are connected in parallel between the transmission device 10 and the reception device 20.

  Each of the communication paths 31 to 3n has an allowable bandwidth that is a bandwidth capable of data transmission. Here, the allowable bandwidth indicates an upper limit bandwidth (for example, bps) that can be used for data transmission in each communication path. In addition, each of the communication paths 31 to 3n is a different communication network, and the allowable bandwidth is also different.

  The communication path in the embodiment of the present invention is a communication network constructed using a terrestrial wireless line, a satellite line, or a carrier line, for example, an IP (Internet Protocol) network path. Each of the communication paths 31 to 3n is constructed by a general network device such as a router or a switch. Each of the communication paths 31 to 3n is also connected to a communication system other than the transmission device 10 and the reception device 20. Therefore, the communication paths 31 to 3n are used other than data communication between the transmission apparatus 10 and the reception apparatus 20, and are not communication paths that can be used exclusively by the communication system 1. The actual line speeds of the communication paths 31 to 3n vary depending on the communication state. Therefore, when data transmission is performed from the transmission device 10 toward the reception device 20, the arrival time of the same data may also change due to the influence of other communications.

  The transmission device 10 sets a transmission band for each of the communication paths 31 to 3n based on the allowable band in each of the communication paths 31 to 3n. Here, the transmission band is a bandwidth for transmitting the data group 11 toward the receiving device 20. In other words, the transmission band refers to a bandwidth actually used by the transmission apparatus 100 for data transmission. Therefore, the transmission device 10 allocates a transmission band for each communication path within a range that does not exceed the allowable band. For example, the transmission device 10 may assign the transmission band equally for each communication path. Alternatively, the transmission device 10 can assign a relatively wide transmission band to a communication path having a larger allowable band. Further, the transmission apparatus 10 may set the transmission band in consideration of the influence of other communication in each communication path.

  Then, the transmission device 10 transmits the same predetermined data group 11 in parallel to each of the communication paths 31 to 3n based on the transmission band set for each of the communication paths 31 to 3n. Here, the data group 11 is a data file to be transmitted, for example, and is divided into a plurality of data strings at the time of transmission. When transmitting the data group 11, the transmitting apparatus 10 simultaneously starts transmitting the first packet of the same predetermined data group 11 to each of the communication paths 31 to 3n. At this time, the transmission apparatus 10 may adjust the packet transmission interval and the packet size (number of data strings) according to the transmission band. Therefore, the data groups 11 as a whole are transmitted in parallel in the communication paths 31 to 3n.

  In addition, the receiving device 20 starts receiving each packet of the data group 11 via each of the communication paths 31 to 3n. Then, when all reception of the predetermined data group 11 via any one of the communication paths 31 to 3n is completed first, the reception device 20 receives the data group 11 that has been received via the communication path. Is valid.

  FIG. 2 is a flowchart showing a flow of data transmission processing according to the first exemplary embodiment of the present invention. First, the transmission device 10 sets a transmission band for each of the communication paths 31 to 3n based on the allowable band in each of the communication paths 31 to 3n (S1). Next, based on the transmission band set for each of the communication paths 31 to 3n, the transmission apparatus 10 transmits the same data group 11 toward the reception apparatus 20 to each of the communication paths 31 to 3n in parallel. (S2).

  For example, the transmission device 10 starts transmission in parallel according to the transmission band for each communication path in order from the first packet in the data group 11. As a result, the same data group 11 is transmitted in parallel to each of the communication paths 31 to 3n. For example, it is assumed that the reception device 20 has completed reception of all the data groups 11 via the communication path 31. In this case, the communication path 31 is an effective path in the transmission of the data group 11 from the transmission apparatus 10 to the reception apparatus 20. Here, the data groups 11 are similarly transmitted on the communication paths 32 to 3n, but as a result, these data groups 11 are not used by the receiving device 20. However, in Embodiment 1 of the present invention, a transmission band considering the allowable band is set for each of the communication paths 31 to 3n, and data is transmitted for each communication path based on the set transmission band. Therefore, an appropriate transmission band can be assigned to each of the communication paths 32 to 3n in order to transmit the data group 11 within the allowable band in the communication paths 32 to 3n. Therefore, an excessive communication load associated with transmission of the data group 11 in the communication paths 32 to 3n can be suppressed.

  On the other hand, even if the transmission of data via the communication path 31 is delayed due to the influence of other communications, the transmission of the data group 11 has already started to the communication paths 32 to 3n in parallel. , Delay of arrival can be minimized. That is, the data group 11 can reach the receiving device 20 faster without having to retransmit the data group 11. From the above, it is possible to suppress an excessive communication load due to simultaneous transmission of data by effectively using a plurality of communication paths.

<Embodiment 2 of the Invention>
The second embodiment of the present invention is an example of the first embodiment described above. FIG. 3 is a block diagram showing a configuration of the communication system 2 according to the second exemplary embodiment of the present invention. The communication system 2 includes a transmission device 100, a reception device 200, and IP networks 301, 302, ..., 30n. The IP networks 301 to 30n are examples of the communication paths 31 to 3n in FIG. For example, the IP network 301 is a terrestrial wireless line, the IP network 302 is a satellite line,..., And the IP network 30n is a carrier line. However, the IP networks 301 to 30n are not limited to this. In addition, the IP networks 301 to 30n have different allowable bands.

  The transmission device 100 includes a transmission processing unit 110, a reception processing unit 120, and a bandwidth control unit 130, and holds a data group 41. The data group 41 is an example of the data group 11, and includes data strings 411, 412, ..., 41m (m is a natural number of 2 or more). The bandwidth control unit 130 sets a transmission bandwidth for each IP network based on each allowable bandwidth of the IP networks 301 to 30n. The transmission processing unit 110 divides the data group 11 into data strings 411 to 41m, adjusts the transmission interval of each data string for each IP network so as to satisfy the transmission bandwidth of each IP network, and sets the IP networks 301 to 30n. For each, transmission of the same data string 411 is started. For example, the transmission processing unit 110 may transmit the same data string to each of the IP networks 301 to 30n by multicast in TCP / IP. In this case, a different multicast address is assigned to each IP network. Then, the transmission processing unit 110 generates and transmits n transmission packets destined for each of the n multicast addresses assigned to the IP networks 301 to 30n. Similarly, the transmission processing unit 110 generates a transmission packet including the data strings 412 to 41m by designating a multicast address. Note that the transmission processing unit 110 plans to transmit at least the data strings 411 to 41m to the IP networks 301 to 30n in this order. However, since the transmission interval is adjusted, packets are not necessarily transmitted simultaneously to each IP network. However, at least at a certain point in time, one of the data strings 411 to 41m is transmitted to each of the IP networks 301 to 30n, so that the data group 41 is transmitted to the IP networks 301 to 30n in parallel.

  The reception processing unit 120 receives a reception confirmation signal from the reception device 200 from any of the IP networks 301 to 30n. Then, when the reception confirmation signal is received, the transmission processing unit 110 transmits a data discard command to the IP network that has not received the reception confirmation signal. For example, when all reception of the data strings 411 to 41n is first completed via the IP network 301 in the reception device 200, the transmission device 100 passes the other IP networks 302 to 30n to the reception device 200. The received data string is discarded. Further, the transmission device 100 causes the reception device 200 to stop receiving subsequent data strings. In addition, when all reception of the data strings 411 to 41n is completed first in the receiving apparatus 200 via any one of the IP networks 301 to 30n, the transmitting apparatus 100 receives the other of the plurality of data strings. The transmission of unsent data strings to the IP network is stopped.

  The receiving device 200 includes a communication processing unit 201, a communication processing unit 202, ..., a communication processing unit 20n. Each of the communication processing units 201 to 20n is an interface corresponding to the IP networks 301 to 30n. However, the communication processing units 201 to 20n do not need to be physically separated, and may be controlled so that data strings are logically transmitted and received for each IP network.

  FIG. 4 is a sequence diagram showing the flow of data transmission processing according to the second embodiment of the present invention. Here, for convenience of explanation, each internal configuration of the communication processing units 201 to 20n in the receiving apparatus 200 will be described. The communication processing unit 201 includes a transmission processing unit 210-1 and a reception processing unit 220-1. The communication processing unit 202 includes a transmission processing unit 210-2 and a reception processing unit 220-2. A transmission processing unit 210-n and a reception processing unit 220-n are provided. Each of the reception processing units 220-1 to 220-n receives data (data string or the like) as transmitted via the corresponding IP networks 301 to 30n. Each of the transmission processing units 210-1 to 210-n transmits a reception confirmation signal to the corresponding IP networks 301 to 30n when the corresponding reception processing unit receives all of the data strings 411 to 41n.

  Further, it is assumed that the bandwidth control unit 130 has already set the transmission bandwidth for each IP network. Based on this assumption, FIG. 4 will be described. First, the transmission processing unit 110 transmits the first data string A (for example, the data string 411) in the data group 41 to each of the IP networks 301 to 30n based on the transmission band (S111, S112,...). S11n). As a result, the reception processing units 220-1 to 220-n receive the data string A, respectively. Subsequently, the transmission processing unit 110 transmits the data string B next to the data string A (for example, the data string 412) to the IP network 301 based on the transmission interval of the IP network 301 (S121). Thereby, the reception processing unit 220-1 receives the data string B. Thereafter, similarly, the transmission processing unit 110 adjusts the transmission interval so as to satisfy the transmission band of each IP network, and appropriately transmits the data string B to each IP network. Here, it is assumed that the transmission interval for the IP network 301 is short. Therefore, the transmission processing unit 110 transmits the last data string M (for example, the data string 41m) in the data group 41 to the IP network 301 (S1M1). Thereby, the reception processing unit 220-1 receives the data string M. For this reason, the communication processing unit 201 has completed reception of all of the data strings A to M, that is, the data group 41. At this time, it is assumed that at least the data string M has not yet been received by the other communication processing units 202 to 20n. That is, the reception of the data group 41 is first completed in the IP network 301 among the IP networks 301 to 30n. Therefore, the transmission processing unit 210-1 transmits a reception confirmation signal to the transmission device 100 via the IP network 301 (S20). Then, the reception processing unit 120 receives a reception confirmation signal via the IP network 301. Therefore, the transmission processing unit 110 transmits a data discard command to each of the IP networks 302 to 30n (S32 to S3n). As a result, the reception processing units 220-2 to 220-n receive the data discard instruction, delete the data string that has already been received and saved in the buffer, and when the data string is received thereafter, Delete the data string without saving it in the buffer.

  Further, even when there is an untransmitted data string at the time of receiving the reception confirmation signal, the transmitting apparatus 100 does not transmit the data string thereafter. This is the case, for example, when the data string M has been transmitted via the IP network 301 but the data string M has not been transmitted to the other IP networks 302 to 30n due to delay or the like.

  As described above, in Embodiment 2 of the present invention, when a plurality of IP networks are connected in parallel between one transmission device and one reception device, and all data is transmitted when one data group is transmitted. The data sequence received from the route that the sequence first arrived at is adopted, and the data sequence via other routes and the data sequence scheduled to be received in the future are discarded. Therefore, even if it is unclear which IP network arrives earlier before transmission, the data group can be transmitted using the fastest route as a result. In addition, since the transmission interval of the data string to each IP network is adjusted so as to satisfy the transmission bandwidth of each IP network, an excessive communication load on each IP network can be suppressed.

<Third Embodiment of the Invention>
Embodiment 3 of the present invention is a modification of Embodiments 1 and 2 described above, and transmits a plurality of data groups in parallel to one receiving apparatus. FIG. 5 is a diagram for explaining the concept of the communication system 3 according to the third embodiment of the present invention. The communication system 3 includes a transmission device 100a, a reception device 200, and IP networks 301 to 303. Here, it is assumed that the transmission device 100a and the reception device 200 are connected in parallel by the IP networks 301 to 303 which are three communication paths.

  The transmission device 100a is a modification of the transmission device 10 and the transmission device 100, includes a transmission processing unit 110a and a bandwidth control unit 130a, and holds data groups 41, 42, and 43. As a configuration not shown, the transmission device 100a also includes a reception processing unit 120. Similar to the data group 41, the data groups 42 and 43 include a plurality of data strings.

  Here, the relationship between the allowable bandwidth and the transmission bandwidth in the IP networks 301 to 303 will be described. For example, it is assumed that the IP network 301 has an allowable bandwidth B1max, the IP network 302 has an allowable bandwidth B2max, and the IP network 303 has an allowable bandwidth B3max. The size of the allowable band is assumed to be in the order of B1max, B2max, and B3max. However, since the IP networks 301 to 303 are also used for other communications, it is not desirable to use all of the allowable bandwidths B1max to B3max. Therefore, the bandwidth control unit 130a sets the transmission bandwidths B1set to B3set according to the allowable bandwidths B1max to B3max in the IP networks 301 to 303, respectively. For example, the bandwidth control unit 130a may set up to a predetermined ratio as the transmission bandwidths B1set to B3set with respect to each allowable bandwidth B1max to B3max. The same applies to the band control unit 130 described above.

  And the transmission process part 110a transmits the data groups 41-43 according to the transmission band B1set-B3set set with respect to each IP network 301-303. Specifically, the transmission processing unit 110a adjusts the transmission interval for each of the IP networks 301 to 303 so as to satisfy the transmission bands B1set to B3set, and transmits each data string to each of the IP networks 301 to 303. At this time, the transmission processing unit 110a starts transmission of the same data group 41 using the communication path R11 that passes through the IP network 301, the communication path R12 that passes through the IP network 302, and the communication path R13 that passes through the IP network 303. To do.

  Next, a case where only the data group 41 is transmitted to the IP networks 301 to 303 will be described. In this case, the bandwidth control unit 130a may set the transmission bandwidths B1set to B3set evenly for the IP networks 301 to 303. Even if the transmission bands B1set to B3set are the same, the time for the same data string to reach the receiving apparatus 200 differs due to the influence of other communications. Further, the bandwidth control unit 130a may set up to a predetermined ratio among the permissible bandwidths B1max to B3max as the transmission bandwidths B1set to B3set. That is, a larger transmission band B1set may be assigned to the IP network 301 having a larger allowable band B1max. In this case, normally, the data group 41 reaches the receiving device 200 the fastest via the IP network 301, but this is not guaranteed due to the influence of other communications. Therefore, it is significant to start transmission in parallel to each IP network by each transmission band.

  Further, the bandwidth control unit 130a may set the transmission bandwidths B1set to B3set according to the communication load status in the IP networks 301 to 303. As a result, it is possible to allocate a transmission band without waste considering the actual load situation, and data can be transmitted more efficiently. Furthermore, after starting the transmission of the data group 41, the bandwidth control unit 130a acquires the communication status other than the transmission of the data group 41 in each of the IP networks 301 to 303, and updates the transmission bandwidths B1set to B3set as appropriate. May be. Then, the transmission processing unit 110 may adjust the transmission interval according to the updated transmission band. That is, the bandwidth control unit 130a may dynamically change the transmission bandwidth during data transmission. In this case, the IP networks 301 to 303 and the receiving apparatus 200 do not need to be aware of the change of the transmission band and the like, and as a result, each data string can be transmitted with the optimum transmission band in each communication path. .

  Next, a case where data groups 42 and 43 in addition to the data group 41 are transmitted to the receiving device 200 will be described. In this case, the bandwidth control unit 130a may equally set all the data groups 41 to 43 as the transmission bandwidths B1set to B3set. However, since there is a difference in the allowable bandwidth as described above, the bandwidth control unit 130a assigns the data groups 41 to 43 to the transmission bandwidth B1set for the IP network 301 having a larger allowable bandwidth, and assigns the data groups 41 and 42 to the transmission bandwidth B2set. And only the data group 41 may be assigned to the transmission band B3set. In this case, the transmission processing unit 110a starts transmission of the data group 42 using the communication path R21 that passes through the IP network 301 and the communication path R22 that passes through the IP network 302. Further, the transmission processing unit 110a starts transmission of the data group 43 using the communication path R31 that passes through the IP network 301. That is, when the bandwidth control unit 130a further transmits other data groups 42 and 43 other than the data group 41 via at least a part of the IP networks 301 to 303, the other data groups 42 and 43 are included. The transmission band is set to be within the allowable band range.

  Further, for example, it is assumed that the data group 43 is added as a transmission target to the receiving device 200 during parallel transmission of the data strings of the two types of data groups 41 and 42. In this case, the bandwidth control unit 130a reduces the transmission bandwidth allocated to the data groups 41 and 42 so as not to exceed each allowable bandwidth by transmitting the data string of the data group 43. Further, it is assumed that transmission of all data strings of the data group 42 is completed during parallel transmission of the data strings of the data groups 41 and 42. In this case, the bandwidth control unit 130a can increase the transmission bandwidth allocated to the data group 41 within a range that does not exceed the allowable bandwidth.

  Thus, a plurality of data groups can be efficiently transmitted according to the allowable bandwidth. Furthermore, the bandwidth control unit 130a may update the transmission bandwidth as appropriate when the data group to be transmitted changes during data transmission.

  FIG. 6 is a flowchart showing a flow of data transmission processing in the transmission device 100a according to the third embodiment of the present invention. First, the transmission device 100a receives an input of a data group (S101). For example, it is assumed that two data groups 41 and 42 are set as transmission targets from the outside. Next, the bandwidth control unit 130a sets transmission bandwidths B1set to B3set based on the allowable bandwidths B1max to B3max of the IP networks 301 to 303 (S102).

  Then, the transmission processing unit 110a performs transmission in units of data strings (S103). That is, the transmission processing unit 110a transmits the data strings included in the data groups 41 and 42 to the IP networks 301 to 303 based on the transmission bands B1set to B3set.

  Then, the transmission device 100a determines whether or not the number of data groups to be transmitted has changed during transmission of the data string (S104). For example, when the data group 43 is added as a transmission target (YES in S104), the transmission bands B1set to B3set are set within the allowable band B1max to B3max so that the data groups 41 to 43 are transmitted in parallel. (S102).

  On the other hand, if the number of data groups to be transmitted does not change during the transmission of the data string, the transmission device 100a determines whether or not the transmission of the data group is completed (S105). Specifically, the transmission processing unit 110a determines whether transmission has been completed in at least one of the IP networks 301 to 303 for at least all data strings in the data group 41. If transmission of the data string has not been completed for any IP network, the process returns to step S103. If it is determined in step S105 that the transmission of the data group to one of the IP networks has been completed (YES in S105), the transmission device 100a waits for reception of a reception confirmation signal from the reception device 200 (S106).

  Then, the transmission device 100a determines whether or not a reception confirmation signal has been received (S107). If the reception confirmation signal has not been received from any IP network, the process returns to step S106. When the reception confirmation signal is received from any IP network, the transmission processing unit 110a transmits a data discard command to the IP network to which the reception confirmation is not transmitted (S108).

  FIG. 7 is a flowchart showing a flow of data reception processing in the receiving apparatus 200 according to the third embodiment of the present invention. In the following, for the sake of explanation, data reception processing for the transmission processing unit 210-1 and the reception processing unit 220-1 of the communication processing unit 201 in the reception device 200 is shown.

  First, the reception processing unit 220-1 starts receiving a data string via the IP network 301 (S201). Thereafter, the reception processing unit 220-1 continues to receive the data string from the IP network 301 (S202). Then, the transmission processing unit 210-1 determines whether or not the reception of all data strings from the IP network 301 has been completed (S203). For example, when it is determined that the reception of all data strings of the data group 41 is completed via the IP network 301, the transmission processing unit 210-1 transmits a reception confirmation signal via the IP network 301 to the transmission device 100a. (S204). On the other hand, if it is determined in step S203 that reception of all data strings has not been completed, the reception processing unit 220-1 determines whether or not a data discard command has been received from the transmission device 100a (S205). If no data discard command has been received, the process returns to step S202. If the data discard command has been received, the communication processing unit 201 stops the subsequent reception and discards the already received data string (S206).

  For example, in FIG. 5, since three data groups 41 to 43 are transmitted from the transmission device 100a, the reception device 200 includes three data groups 41 via communication paths R11, R12, and R13, and a communication path. Two data groups 42 that pass through each of R21 and R22 and one data group 43 that passes through the communication path R31 can arrive. Here, in the third embodiment of the present invention, for the data group 41, the data string that passes through the IP network to which all packets have arrived the fastest among the IP networks 301 to 303 is valid, and the data group 42 is the IP network. The data string that passes through the IP network in which all the packets reach the fastest of 301 and 302 is made valid.

  In this way, by setting the transmission bandwidth according to the difference in the allowable bandwidth of each IP network, it is possible to transmit data faster by effectively utilizing the bandwidth while suppressing an excessive communication load on each IP network. it can. Furthermore, since the transmission bandwidth is dynamically updated in response to changes in the actual communication status of each IP network during data transmission, the transmission interval can be flexibly adjusted, resulting in efficient use of each IP network. Parallel transmission can be realized.

<Embodiment 4 of the Invention>
The fourth embodiment of the present invention is an application example of the above-described first to third embodiments. Embodiment 4 of the present invention describes means for efficiently distributing data in one-to-many communication using a plurality of parallel IP networks.

  FIG. 8 is a block diagram showing a configuration of the communication system 4 according to the fourth exemplary embodiment of the present invention. In the communication system 4, a plurality of IP networks 301 to 30n are connected in parallel between one transmission device 100b and a plurality of reception devices 200-1, 200-2, ..., 200-n. The case where the same data group is transmitted to each receiving apparatus is targeted. Note that each of the receiving devices 200-1 to 200-n has a configuration equivalent to that of the receiving device 200 described above.

  The transmission device 100b is a modification of the transmission device 10, the transmission device 100, and the transmission device 100a described above. The transmission device 100b sets a transmission band within the allowable band in order to transmit one data group to the reception devices 200-1 to 200-n. Then, the transmission device 100b starts transmitting the same data group in parallel to each of the IP networks 301 to 30n with the reception devices 200-1 to 200-n as destinations based on the transmission band. Then, in each of the receiving apparatuses 200-1 to 200-n, the data group that has been received via the IP network in which the reception of the predetermined data group is first completed is validated. For this reason, even in the same data group, if the receiving device is different, the communication path transmitted at the fastest speed may be different. Note that the data group to be transmitted is not limited to one type, and two or more types can be applied.

  FIG. 9 is a diagram for explaining the concept of the communication system 4 according to the fourth embodiment of the present invention. FIG. 9 shows a case where the valid IP networks are different in each of the receiving apparatuses 200-1 to 200-n. Note that the internal routes of the IP networks 301 to 30n are not considered. Then, it is assumed that the allowable bands are different for the IP networks 301 to 30n. In this case, there are three lines each connecting the transmission device 100b and each of the reception devices 200-1 to 200-n. Here, for example, the effective route R11v via the IP network 301 is the fastest between the transmitting device 100b and the receiving device 200-1, and the redundant route via the IP network 301 and the redundant route via the IP network 30n. Rn1x can be redundant. The effective route Rn2v via the IP network 30n is the fastest between the transmission device 100b and the reception device 200-2, and the redundant routes R12x and R22x via the IP networks 301 and 302 may be redundant. . In addition, the effective route R2nv via the IP network 302 is the fastest between the transmission device 100b and the reception device 200-n, and the redundant routes R1nx and Rnnx via the IP networks 301 and 30n may be redundant. . Therefore, in the fourth embodiment of the present invention, the same data group is transmitted from the transmission device 100b to each of the reception devices 200-1 to 200-n via the IP networks 301 to 30n. The data group can be transmitted more quickly without selecting an optimal route in advance from the combination of the IP network and each receiving device.

<Other embodiments>
Furthermore, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention described above. For example, in the above-described embodiment, the present invention has been described as a hardware configuration, but the present invention is not limited to this. The present invention can also realize arbitrary processing by causing a CPU (Central Processing Unit) to execute a computer program. In this case, the computer program can be stored using various types of non-transitory computer readable media and supplied to the computer.

  Non-transitory computer readable media include various types of tangible storage media. Examples of non-transitory computer-readable media include magnetic recording media (for example, flexible disks, magnetic tapes, hard disk drives), magneto-optical recording media (for example, magneto-optical disks), CD-ROMs (Read Only Memory), CD-Rs, CD-R / W, DVD (Digital Versatile Disc), BD (Blu-ray (registered trademark) Disc), semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM ( Random Access Memory)). The computer program may also be supplied to the computer by various types of transitory computer readable media. Examples of transitory computer readable media include electrical signals, optical signals, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire and an optical fiber, or a wireless communication path.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 Communication system 2 Communication system 3 Communication system 4 Communication system 10 Transmission apparatus 11 Data group 20 Reception apparatus 31 Communication path 32 Communication path 3n Communication path 100a Transmission apparatus 100b Transmission apparatus 100 Transmission apparatus 110 Transmission process part 110a Transmission process part 120 Reception process Unit 130 bandwidth control unit 130a bandwidth control unit 41 data group 411 data sequence 412 data sequence 41m data sequence 42 data group 43 data group 200 receiving device 200-1 receiving device 200-2 receiving device 200-n receiving device 201 communication processing unit 210 -1 transmission processing unit 220-1 reception processing unit 202 communication processing unit 210-2 transmission processing unit 220-2 reception processing unit 20n communication processing unit 210-n transmission processing unit 220-n reception processing unit 301 IP network 302 IP network 303 IP network 30 IP network R11 communication path R12 communication path R13 communication path R21 communication path R22 communication path R31 communication path B1max allowable band B1set transmission band B2max allowable band B2set transmission band B3max allowable band B3set transmission band R11v effective path R12x redundant path R1nx redundant path R21x redundant path R22x Redundant route R2nv Effective route Rn1x Redundant route Rn2v Effective route Rnnx Redundant route

Claims (10)

A bandwidth for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel with the receiving device. Set a transmission band for each of the plurality of communication paths,
A transmission apparatus that transmits the same predetermined data group in parallel to each of the plurality of communication paths based on the transmission band set for each of the plurality of communication paths. Dividing the predetermined data group into a plurality of data strings;
The transmission apparatus according to claim 1, wherein a transmission interval of each data string is adjusted for each of the plurality of communication paths so as to satisfy the transmission band, and each data string is transmitted to each of the plurality of communication paths. When all reception of the plurality of data strings is first completed via any one of the plurality of communication paths in the reception apparatus, reception is performed via the other communication paths to the reception apparatus. The transmitting apparatus according to claim 2, wherein the already-completed data string is discarded. When all reception of the plurality of data strings is first completed via any one of the plurality of communication paths in the receiving device, the other communication paths of the plurality of data strings are not yet received. The transmission apparatus according to claim 2, wherein transmission of a transmission data string is stopped. After starting transmission of the predetermined data group, update the transmission band according to the communication status other than the predetermined data group in each of the plurality of communication paths,
The transmission device according to any one of claims 2 to 4, wherein the transmission interval is adjusted according to the updated transmission band. When further transmitting a data group other than the predetermined data group via at least a part of the plurality of communication paths, the data including the other data group is included in the allowable bandwidth range. The transmission apparatus according to any one of claims 1 to 5, wherein a transmission band is set. Setting the transmission band within the allowable band in order to transmit the predetermined data group to two or more receiving devices;
7. The same predetermined data group is transmitted in parallel to each of the plurality of communication paths with the two or more receiving devices as destinations based on the transmission band. The transmitting device described. A transmission device and a reception device connected to the transmission device by a plurality of parallel communication paths;
The transmitter is
A transmission band that is a bandwidth for transmitting a predetermined data group toward the receiving device is set for each of the plurality of communication paths based on an allowable band that is a bandwidth capable of data transmission in each of the plurality of communication paths. Set,
A communication system that transmits the same predetermined data group in parallel to each of the plurality of communication paths based on the transmission band set for each of the plurality of communication paths. A band for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel between the transmitting device and the receiving device. A transmission band that is a width is set for each of the plurality of communication paths,
A data transmission method for transmitting the same predetermined data group in parallel to each of the plurality of communication paths from the transmission device based on the transmission band set for each of the plurality of communication paths. A bandwidth for transmitting a predetermined data group to the receiving device based on an allowable bandwidth that is a bandwidth capable of data transmission in each of a plurality of communication paths connected in parallel with the receiving device. A process of setting a transmission band for each of the plurality of communication paths;
A process of transmitting the same predetermined data group in parallel to each of the plurality of communication paths, based on the transmission band set for each of the plurality of communication paths;
Data transmission program that causes a computer to execute.

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