JP6640129B2 - Communication device, communication method, and computer program - Google Patents

Description

  The present invention relates to a communication device, a communication method, and a computer program.

  A technology for performing wireless communication by simultaneously using a plurality of wireless communication systems is described in, for example, Patent Document 1.

JP 2013-207731 A

  When performing wireless communication with a communication partner by simultaneously using a plurality of wireless communication systems, if the transmission delay time of the communication path of each wireless communication system is different, the order of packets arriving at the communication partner will be reversed, and the packet will be lost. In such a case, it takes time and effort to restore the order, and the communication efficiency may be reduced.

  The present invention has been made in view of such circumstances, and an object of the present invention is to improve communication efficiency when performing communication with a communication partner by simultaneously using a plurality of communication paths.

(1) One embodiment of the present invention includes a plurality of communication units that perform communication using a communication line, a packet transmission / reception unit provided corresponding to each of the plurality of communication units, and a plurality of the packet transmission / reception units. A communication control unit for simultaneously communicating with the communication partner using the communication control unit, and the plurality of packet transmission / reception units simultaneously used for communication with the communication partner each of which includes a reception interval of an acknowledgment signal received from the communication partner. A transmission timing instructing unit that instructs a packet transmission timing of the plurality of packet transmitting / receiving units based on a longest reception interval , wherein the packet transmitting / receiving unit has a self-clocking function, A transmitting / receiving unit that generates a self-clocking transmission timing signal in synchronization with a reception timing of its own acknowledgment signal; A transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the plurality of packet transmission / reception units simultaneously used for communication with the communication partner. Based on the locking transmission timing signal, the interval of the self-clocking transmission timing signal is measured for each of the plurality of packet transmission / reception units, and based on the measurement result, the plurality of packets are transmitted at the longest interval of the self-clocking transmission timing signal. This is a communication device that adjusts the packet transmission timing of the transmitting / receiving unit .
( 2 ) In one aspect of the present invention, in the communication device described above, any one of the packet transmitting / receiving units is used for communication with the communication partner based on the reception interval, or any of a plurality of The communication device further includes a communication path selection unit that selects whether to use the packet transmission / reception unit.

( 3 ) One embodiment of the present invention is a communication system comprising: a plurality of communication units that perform communication using a communication line; a packet transmission / reception unit provided for each of the plurality of communication units; and a plurality of the packet transmission / reception units. A communication control unit that performs communication with a communication partner by using the communication partner simultaneously, wherein the plurality of packet transmission / reception units simultaneously used for communication with the communication partner are respectively transmitted from the communication partner. A transmission timing instructing a packet transmission timing of the plurality of packet transmission / reception units based on a longest reception interval among reception intervals of an acknowledgment signal to be received , wherein the packet transmission / reception unit includes It has a clocking function, and the packet transmission / reception unit generates a self-clocking transmission timing signal in synchronization with the reception timing of its own acknowledgment signal. The communication device further includes a transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the packet transmission / reception unit, wherein the transmission timing instructing step includes the plurality of packets simultaneously used for communication with the communication partner. Based on the self-clocking transmission timing signals generated respectively by the transmission and reception units, the intervals of the self-clocking transmission timing signals are measured for each of the plurality of packet transmission and reception units, and the longest self-clocking is performed based on the measurement result. A communication method, wherein packet transmission timings of the plurality of packet transmission / reception units are adjusted to intervals of transmission timing signals .

( 4 ) One aspect of the present invention is a communication system comprising: a plurality of communication units that perform communication using a communication line; a packet transmission / reception unit provided for each of the plurality of communication units; and a plurality of the packet transmission / reception units. A communication control unit that performs communication with the communication partner by using the communication partner at the same time, the plurality of packet transmission / reception units simultaneously used for communication with the communication partner receive from the communication partner, respectively. based on the longest reception interval of the reception intervals of an acknowledgment signal, transmission timing instruction function for instructing a packet transmission timing of the plurality of packet transmitting and receiving unit, a computer program for realizing the packet transceiver unit is self The packet transmission / reception unit has a clocking function, and the packet transmission / reception unit transmits a self-clocking signal in synchronization with a reception timing of its own acknowledge signal. Generating a timing signal, the communication device further includes a transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the packet transmission / reception unit, and the transmission timing instruction function is used simultaneously for communication with the communication partner. Based on the self-clocking transmission timing signal generated by each of the plurality of packet transmission / reception units, an interval between the self-clocking transmission timing signals is measured for each of the plurality of packet transmission / reception units, and based on a result of the measurement. A computer program for adjusting a packet transmission timing of the plurality of packet transmission / reception units to an interval of a longest self-clocking transmission timing signal .

  Advantageous Effects of Invention According to the present invention, it is possible to improve communication efficiency when performing communication with a communication partner by simultaneously using a plurality of communication paths.

FIG. 1 is a block diagram illustrating a schematic configuration of a communication device 10 according to an embodiment. 5 is a flowchart illustrating a procedure of a communication method according to an embodiment. FIG. 3 is an explanatory diagram of a communication method according to one embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram illustrating a schematic configuration of a communication device 10 according to an embodiment. In FIG. 1, a communication device 10 includes an application unit 11, a multipath transmission control protocol (MPTCP) unit 12, a transmission control protocol (TCP), and an Internet protocol (IP). It includes units 13-1 and 13-2, wireless communication units 14-1 and 14-2, a transmission timing acquisition unit 15, a transmission timing instruction unit 16, and a communication path selection unit 17. The TCP / IP unit 13-1 includes a transmission control unit 20, a transmission unit 22, and a reception unit 23. The transmission control unit 20 includes a self-clocking unit 21. The TCP / IP unit 13-2 has the same configuration as the TCP / IP unit 13-1.

  In the following description, the TCP / IP units 13-1 and 13-2 are referred to as the TCP / IP units 13 unless otherwise distinguished. When the wireless communication units 14-1 and 14-2 are not particularly distinguished, they are referred to as the wireless communication unit 14.

  Note that the communication device 10 according to the present embodiment includes two wireless communication units 14, but may include three or more wireless communication units 14. The TCP / IP unit 13 is provided corresponding to each of the plurality of wireless communication units 14. The TCP / IP unit 13-1 is provided corresponding to the wireless communication unit 14-1. The TCP / IP unit 13-2 is provided corresponding to the wireless communication unit 14-2. In the present embodiment, the TCP / IP unit 13 corresponds to a packet transmitting / receiving unit.

  The application unit 11 is an application provided in the communication device 10 and has at least a function of an application that performs communication. For example, the application unit 11 has a function of uploading photograph data, moving image data, file data, and the like to a server or the like through communication.

  The MPTCP unit 12 performs communication with a communication partner by simultaneously using a plurality of TCP connections. In the present embodiment, the MPTCP unit 12 corresponds to a communication control unit.

  The TCP / IP unit 13 performs a TCP process and an IP process. FIG. 1 shows only a part of the TCP processing and the IP processing that executes the processing according to the present embodiment.

  The transmitting unit 22 transmits the packet Ps. The packet Ps is a packet based on TCP and IP. The transmission control unit 20 controls transmission of the packet Ps. The transmission control unit 20 outputs a packet transmission control signal E to the transmission unit 22. The packet transmission control signal E is a signal that instructs the transmission unit 22 to transmit the packet Ps. The transmission unit 22 transmits the packet Ps to the wireless communication unit 14 according to the packet transmission control signal E. The transmission unit 22 of the TCP / IP unit 13-1 transmits the packet Ps to the wireless communication unit 14-1. The wireless communication unit 14-1 transmits the packet Ps received from the transmission unit 22 of the TCP / IP unit 13-1 via a wireless communication line. The transmission unit 22 of the TCP / IP unit 13-2 transmits the packet Ps to the wireless communication unit 14-2. The wireless communication unit 14-2 transmits the packet Ps received from the transmission unit 22 of the TCP / IP unit 13-2 via a wireless communication line.

  The receiving unit 23 receives the packet Pr from the wireless communication unit 14. The packet Pr is a packet based on TCP and IP. The wireless communication unit 14-1 transmits the packet Pr received via the wireless communication line to the receiving unit 23 of the TCP / IP unit 13-1. The wireless communication unit 14-2 transmits the packet Pr received via the wireless communication line to the receiving unit 23 of the TCP / IP unit 13-2. The reception unit 23 outputs to the transmission control unit 20 an ACK reception timing signal F indicating the reception timing of the packet of the acknowledgment signal (ACK packet) among the packets Pr received from the wireless communication unit 14.

  The self-clocking unit 21 has a TCP self-clocking function. The self-clocking unit 21 generates a self-clocking transmission timing signal in synchronization with the ACK reception timing signal F. The self-clocking unit 21 of the TCP / IP unit 13-1 generates a self-clocking transmission timing signal A1. The self-clocking unit 21 of the TCP / IP unit 13-1 outputs a self-clocking transmission timing signal A1 to the transmission timing acquisition unit 15. The self-clocking unit 21 of the TCP / IP unit 13-2 generates a self-clocking transmission timing signal A2. The self-clocking unit 21 of the TCP / IP unit 13-2 outputs the self-clocking transmission timing signal A2 to the transmission timing acquisition unit 15.

  The transmission timing acquisition unit 15 receives the self-clocking transmission timing signal A1 from the self-clocking unit 21 of the TCP / IP unit 13-1. The transmission timing acquisition unit 15 receives the self-clocking transmission timing signal A2 from the self-clocking unit 21 of the TCP / IP unit 13-2. The transmission timing acquisition unit 15 measures a reception interval of the self-clocking transmission timing signal A1. The transmission timing acquisition unit 15 measures a reception interval of the self-clocking transmission timing signal A2. The transmission timing acquisition unit 15 sends a reception interval signal B indicating the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2 to the transmission timing instruction unit 16 and the communication path selection unit 17. Output.

  Using the reception interval signal B, the transmission timing instructing section 16 compares the reception interval of the self-clocking transmission timing signal A1 with the reception interval of the self-clocking transmission timing signal A2, and determines the longer reception interval. I do. The transmission timing instructing section 16 generates the packet transmission timing signal C based on the longer one of the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2.

  The packet transmission timing signal C is a signal indicating the transmission timing of the packet Ps. For example, the packet transmission timing signal C is a signal indicating the transmission start time of the packet Ps and the transmission interval of the packet Ps. The transmission timing of the packet Ps indicated by the packet transmission timing signal C is set to the longer reception interval of the self-clocking transmission timing signal A1 and the self-clocking transmission timing signal A2. That is, the transmission interval of the packet Ps is set to match the longer one of the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2.

  The transmission timing instructing unit 16 outputs the same packet transmission timing signal C to both the TCP / IP units 13-1 and 13-2. The transmission control unit 20 of the TCP / IP unit 13 generates a packet transmission control signal E according to the transmission timing of the packet Ps indicated by the packet transmission timing signal C, and outputs it to the transmission unit 22. As a result, in the TCP / IP unit 13-1 and the wireless communication unit 14-1, and the TCP / IP unit 13-2 and the wireless communication unit 14-2, the packet Ps is generated by the self-clocking transmission timing signals A1 and A2. The transmission unit 22 transmits to the wireless communication unit 14 at a transmission interval that matches the longer one of the reception intervals, and then transmits from the wireless communication unit 14 via a wireless communication line.

  The wireless communication unit 14 transmits the packet Ps via a wireless communication line. The wireless communication unit 14 receives the packet Pr via a wireless communication line. The wireless communication line used by the wireless communication unit 14 may be a wireless communication line of a mobile communication network such as a mobile phone network or a wireless communication line of a wireless LAN (Local Area Network). The wireless communication unit 14-1 and the wireless communication unit 14-2 use different wireless communication lines. The wireless communication line used by the wireless communication unit 14-1 and the wireless communication line used by the wireless communication unit 14-2 may be different wireless communication lines of the same wireless communication network, or different wireless communication networks. Wireless communication line.

  The communication path selection unit 17 uses the reception interval signal B to select which one of the TCP / IP units 13 is to be used or which of the plurality of TCP / IP units 13 is to be used. In the present embodiment, the communication path selection unit 17 uses the reception interval signal B to determine which one of the TCP / IP units 13-1 and 13-2 to use, or Whether to use both of the TCP / IP units 13-1 and 13-2 is selected.

This TCP / IP section selection method will be described.
According to the packet transmission timing signal C described above, the packet Ps is transmitted at a transmission interval that matches the longer one of the self-clocking transmission timing signals A1 and A2. Therefore, in the TCP / IP unit 13 having the shorter reception interval of the self-clocking transmission timing signal, the transmission timing of the packet Ps is later than the transmission timing of the self-clocking transmission timing signal, and the transmission of the packet Ps is correspondingly delayed. Will be waited for. Therefore, which one of the TCP / IP units 13-1 and 13-2 uses the TCP / IP unit 13 has a higher communication speed, or the TCP / IP units 13-1 and 13-2. It is determined whether the communication speed is faster when both are used.

  Based on the reception interval signal B, the communication path selecting unit 17 determines a communication speed V1 when using only the TCP / IP unit 13-1 and a communication speed V2 when using only the TCP / IP unit 13-2. , The communication speed V12 when both of the TCP / IP units 13-1 and 13-2 are used is determined. The communication path selection unit 17 selects one of the TCP / IP units 13 or both of the TCP / IP units 13-1 and 13-2 determined to have the highest communication speed.

  The communication path selection unit 17 outputs a TCP / IP unit selection result signal D indicating the selection result of the TCP / IP unit 13 to the MPTCP unit 12 and the transmission timing instruction unit 16. The MPTCP unit 12 uses the TCP / IP unit 13 of the selection result indicated by the TCP / IP unit selection result signal D for communication with a communication partner.

  When the selection result indicated by the TCP / IP section selection result signal D is both of the TCP / IP sections 13-1 and 13-2, the transmission timing instructing section 16 sends the packet transmission timing signal C to the TCP / IP section. 13-1 and 13-2. On the other hand, if the selection result indicated by the TCP / IP unit selection result signal D is one TCP / IP unit 13, the transmission timing instruction unit 16 does not output the packet transmission timing signal C. Therefore, when the selection result indicated by the TCP / IP unit selection result signal D is one TCP / IP unit 13, the packet transmission timing signal C is transmitted to both the TCP / IP unit 13-1 and the TCP / IP unit 13-1. -2 is not output.

  When receiving the packet transmission timing signal C from the transmission timing instruction unit 16, the transmission control unit 20 of the TCP / IP unit 13 generates a packet transmission control signal E according to the packet transmission timing signal C. On the other hand, when the transmission control unit 20 of the TCP / IP unit 13 does not receive the packet transmission timing signal C from the transmission timing instruction unit 16, it generates the packet transmission control signal E by the conventional TCP processing.

  The communication device 10 may be, for example, a mobile communication terminal device such as a smartphone or a tablet computer (tablet PC), or a stationary communication terminal device (for example, a stationary personal computer or a server computer). Etc.).

  Each unit of the communication device 10 illustrated in FIG. 1 may be realized by dedicated hardware, or may be configured by a CPU (Central Processing Unit), a memory, and the like. The functions may be realized by a CPU executing a computer program for realizing the functions.

  Next, the procedure of the communication method according to the present embodiment will be described with reference to FIG. FIG. 2 is a flowchart illustrating a procedure of the communication method according to the present embodiment.

  In the communication device 10, the MPTCP unit 12 starts communication with a communication partner in response to an instruction from the application unit 11. At the start of communication, the MPTCP unit 12 uses a plurality of TCP / IP units 13 and the wireless communication unit 14 to communicate with a communication partner. In this embodiment, the MPTCP unit 12 uses the TCP / IP unit 13-1 and the wireless communication unit 14-1, and the TCP / IP unit 13-2 and the wireless communication unit 14-2 to communicate with the communication partner. Perform communication. The communication path of the TCP / IP unit 13-1 and the wireless communication unit 14-1 is different from the communication path of the TCP / IP unit 13-2 and the wireless communication unit 14-2.

(Step S1) The transmission timing acquisition unit 15 acquires the self-clocking transmission timing signal A1 from the TCP / IP unit 13-1. The transmission timing acquisition unit 15 acquires the self-clocking transmission timing signal A2 from the TCP / IP unit 13-2. The transmission timing acquisition unit 15 sends a reception interval signal B indicating the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2 to the transmission timing instruction unit 16 and the communication path selection unit 17. Output.

(Step S2) The communication path selection unit 17 uses any one of the TCP / IP units 13 (one communication path) among the TCP / IP units 13-1 and 13-2 using the reception interval signal B. Or whether to use both of the TCP / IP units 13-1 and 13-2 (a plurality of communication paths). The communication path selection unit 17 outputs a TCP / IP unit selection result signal D indicating the selection result of the TCP / IP unit 13 to the MPTCP unit 12 and the transmission timing instruction unit 16.

(Step S3) In step S2, if both of the TCP / IP units 13-1 and 13-2 (a plurality of communication paths) are selected, the process proceeds to step S4. If not, the process of FIG. finish.

(Step S4) Based on the reception interval signal B, the transmission timing instructing section 16 sets the longer reception interval between the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2. Based on this, a packet transmission timing signal C is generated. The packet transmission timing signal C is a signal for adjusting the transmission timing of the packet Ps to the longer reception interval of the reception interval of the self-clocking transmission timing signal A1 and the reception interval of the self-clocking transmission timing signal A2. The transmission timing instructing unit 16 outputs the same packet transmission timing signal C to both the TCP / IP units 13-1 and 13-2. As a result, in the TCP / IP unit 13-1 and the wireless communication unit 14-1, and the TCP / IP unit 13-2 and the wireless communication unit 14-2, the packet Ps is generated by the self-clocking transmission timing signals A1 and A2. The transmission unit 22 transmits to the wireless communication unit 14 at a transmission interval that matches the longer one of the reception intervals, and then transmits from the wireless communication unit 14 via a wireless communication line.

  Note that the process of FIG. 2 may be executed again when a predetermined start condition is satisfied. For example, the processing in FIG. 2 may be repeatedly executed at a predetermined cycle. Alternatively, the process of FIG. 2 may be executed again when the state of the wireless communication line of the wireless communication unit 14 changes. Examples of the case where the state of the wireless communication line changes include a case where the line quality changes and a case where the line is reconnected.

  FIG. 3 is an explanatory diagram of the communication method according to the present embodiment. In FIG. 3, a communication device 10-1 is a communication device on the transmission side. The communication device 10-2 is a communication device on the receiving side, which is a communication partner of the communication device 10-1. In the embodiment of FIG. 3, the communication device 10 of FIG. 1 is applied to the communication devices 10-1 and 10-2. Note that the communication device 10-2 on the receiving side may be a communication device that performs conventional MPTCP processing, TCP processing, and IP processing.

  In the communication device 10-1, the application unit (app) 11 outputs, to the MPTCP unit 12, ten packets whose sequence numbers are 1 to 10 as a packet sequence. In accordance with the TCP / IP unit selection result signal D, the MPTCP unit 12 communicates with the communication partner communication device 10-2 using both the TCP / IP units 13-1 and 13-2. The MPTCP unit 12 allocates the five packets having the sequence numbers 1, 3, 5, 7, and 9 to the TCP / IP unit 13-1. The MPTCP unit 12 allocates the five packets having the sequence numbers 2, 4, 6, 8, and 10 to the TCP / IP unit 13-2. In FIG. 3, a packet P represents a packet waiting for transmission before transmission, and a packet Ps represents a transmitted packet.

  In the example of FIG. 3, the packet transmission speed of the communication path 101 of the TCP / IP unit 13-1 is lower than that of the communication path 102 of the TCP / IP unit 13-2. Therefore, the reception interval of the self-clocking transmission timing signal A1 is longer than the reception interval of the self-clocking transmission timing signal A2. Thereby, the packet transmission timing signal C of the communication device 10-1 becomes a signal that adjusts the transmission timing of the packet Ps to the reception interval of the self-clocking transmission timing signal A1.

  The TCP / IP units 13-1 and 13-2 of the communication device 10-1 transmit the packet Ps according to the packet transmission timing signal C. As a result, in the communication device 10-1, the packet Ps transmitted from the TCP / IP unit 13-1 and the packet Ps transmitted from the TCP / IP unit 13-2 are communicated by the TCP / IP unit 13-1. The packet is transmitted according to the transmission speed of the packet on the route 101.

  A packet sequence “packets Ps having sequence numbers 1, 3, and 5” transmitted from the communication device 10-1 via the communication path 101 and the packet sequence transmitted from the communication device 10-1 via the communication path 102 The packet sequence “the packets Ps having the second, fourth, and sixth sequence numbers” arrives at the communication device 10-2 in synchronization with the packet transmission speed of the communication path 101. As a result, the packet transmission speed of the communication path 101 differs from that of the communication path 102, but the communication device 10-2 can sequentially receive the packets Ps along the sequence number of the packets Ps. , The communication efficiency can be prevented from lowering, and the communication efficiency can be improved.

  The communication device 10-1 may transmit a retransmission packet to the communication device 10-2 during the idle time Q of the communication path 102 of the TCP / IP unit 13-2. Since the communication path 102 of the TCP / IP unit 13-2 has a higher packet transmission speed than the communication path 101 of the TCP / IP unit 13-1, the transmission path of the communication path 102 is set to match the transmission rate of the packet of the communication path 101. When the packet Ps is transmitted, a free time Q occurs. By transmitting the retransmission packet during the idle time Q, communication efficiency can be improved.

  According to the above-described embodiment, it is possible to improve communication efficiency when performing communication with a communication partner by simultaneously using a plurality of communication paths.

  According to the present embodiment, the packet transmission control is performed based on the reception interval of the acknowledgment signal of each communication path received from the communication partner, so that the packet transmission control is performed according to the fluctuation of the packet transmission speed of each communication path No need. As a result, the packet transmission control can be simplified as compared with the case where the packet transmission control is performed according to the fluctuation of the packet transmission speed of each communication path. This is also preferable for a communication network in which it is difficult to observe the quality (packet transmission speed) of all wireless sections in real time, such as a multi-hop wireless network.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiments, and includes a design change or the like without departing from the gist of the present invention.

  For example, in the above-described embodiment, the communication device 10 performs communication with a communication partner by simultaneously using a plurality of wireless communication lines, but the communication line used by the communication device 10 may be a wired communication line. For example, the communication device 10 may communicate with a communication partner using a plurality of wired communication lines simultaneously. Alternatively, the communication device 10 may perform communication with a communication partner by simultaneously using one or a plurality of wireless communication lines and one or a plurality of wired communication lines.

  When the communication device 10 communicates with a communication partner using three or more communication lines simultaneously, the transmission timing instructing unit 16 outputs an acknowledgment signal received from the communication partner via each communication line. The packet transmission timings of the plurality of TCP / IP units 13 may be instructed based on the relatively longer reception interval among the above reception intervals. For example, it may be based on the longest reception interval, or may be based on any reception interval longer than the intermediate length. However, in order to suppress the occurrence of packet reversal as much as possible, it is preferable to use the longest reception interval.

  As a modified example of the above-described embodiment, the transmission timing instructing unit 16 synchronizes with the self-clocking transmission timing signal A1, A2 having the longer reception interval to transmit the packet transmission timing signal. C may be generated and the same packet transmission timing signal C may be output to both the TCP / IP units 13-1 and 13-2. In this modification, the transmission control unit 20 of the TCP / IP unit 13 generates a packet transmission control signal E and outputs it to the transmission unit 22 in synchronization with the packet transmission timing signal C. As a result, in the TCP / IP unit 13-1 and the wireless communication unit 14-1, and the TCP / IP unit 13-2 and the wireless communication unit 14-2, the packet Ps is generated by the self-clocking transmission timing signals A1 and A2. The transmission section 22 transmits the signal to the wireless communication section 14 in synchronization with the self-clocking transmission timing signal having the longer reception interval, and then transmits the wireless communication section 14 via the wireless communication line.

Further, a computer program for realizing the functions of the communication device 10 described above may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read and executed by a computer system. . Here, the “computer system” may include an OS and hardware such as peripheral devices.
The “computer-readable recording medium” includes a writable nonvolatile memory such as a flexible disk, a magneto-optical disk, a ROM, and a flash memory, a portable medium such as a DVD (Digital Versatile Disc), and a computer system. Storage device such as a hard disk.

Further, a “computer-readable recording medium” refers to a volatile memory (for example, a DRAM (Dynamic Dynamic Memory)) in a computer system that serves as a server or a client when a program is transmitted through a network such as the Internet or a communication line such as a telephone line. Random Access Memory), which holds programs for a certain period of time.
Further, the above program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting a program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
Further, the program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 10 ... Communication device, 11 ... Application part, 12 ... MPTCP part, 13-1, 13-2 ... TCP / IP part, 14-1, 14-2 ... Wireless communication part, 15 ... Transmission timing acquisition part, 16 ... Transmission Timing instructing unit, 17 communication path selecting unit, 20 transmission control unit, 22 transmitting unit, 23 receiving unit, 21 self-clocking unit

Claims (4)

A plurality of communication units that communicate using a communication line;
A packet transmitting / receiving unit provided corresponding to each of the plurality of communication units;
A communication control unit that performs communication with a communication partner by simultaneously using a plurality of the packet transmission / reception units;
Based on the longest reception interval among the reception intervals of the acknowledgment signal received by the plurality of packet transmission / reception units simultaneously used for communication with the communication partner, from the plurality of packet transmission / reception units, A transmission timing instructing unit for instructing a transmission timing ,
The packet transmitting / receiving unit has a self-clocking function,
The packet transmitting and receiving unit generates a self-clocking transmission timing signal in synchronization with the reception timing of its own acknowledgment signal,
The communication device,
Further comprising a transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the packet transmission / reception unit,
The transmission timing instructing unit is configured to self-clock for each of the plurality of packet transmission / reception units based on the self-clocking transmission timing signal generated by each of the plurality of packet transmission / reception units simultaneously used for communication with the communication partner. Measure the interval of the locking transmission timing signal, adjust the packet transmission timing of the plurality of packet transmission and reception unit to the interval of the longest self-clocking transmission timing signal based on the result of the measurement,
Communication device. Based on the reception interval, for communication with the communication partner, whether to use any one of the packet transmission and reception unit, or a communication path selection unit to select which of the plurality of packet transmission and reception unit to use Further prepare,
The communication device according to claim 1 . A plurality of communication units performing communication using a communication line, a packet transmission / reception unit provided corresponding to each of the plurality of communication units, and a communication with a communication partner using the plurality of packet transmission / reception units simultaneously. A communication control unit for performing, a communication method of a communication device comprising:
Based on the longest reception interval among the reception intervals of the acknowledgment signal received by the plurality of packet transmission / reception units simultaneously used for communication with the communication partner, from the plurality of packet transmission / reception units, A transmission timing indicating step of indicating a transmission timing, comprising :
The packet transmitting / receiving unit has a self-clocking function,
The packet transmitting and receiving unit generates a self-clocking transmission timing signal in synchronization with the reception timing of its own acknowledgment signal,
The communication device,
Further comprising a transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the packet transmission / reception unit,
The transmission timing instructing step includes, based on the self-clocking transmission timing signal generated by each of the plurality of packet transmission / reception units simultaneously used for communication with the communication partner, self-clocking for each of the plurality of packet transmission / reception units. Measure the interval of the locking transmission timing signal, adjust the packet transmission timing of the plurality of packet transmission and reception unit to the interval of the longest self-clocking transmission timing signal based on the result of the measurement,
Communication method. A plurality of communication units performing communication using a communication line, a packet transmission / reception unit provided corresponding to each of the plurality of communication units, and a communication with a communication partner using the plurality of packet transmission / reception units simultaneously. A communication control unit that performs
Based on the longest reception interval among the reception intervals of the acknowledgment signal received by the plurality of packet transmission / reception units simultaneously used for communication with the communication partner, from the plurality of packet transmission / reception units, A transmission timing instruction function for instructing transmission timing, a computer program for realizing ,
The packet transmitting / receiving unit has a self-clocking function,
The packet transmitting and receiving unit generates a self-clocking transmission timing signal in synchronization with the reception timing of its own acknowledgment signal,
The communication device,
Further comprising a transmission timing acquisition unit that acquires a self-clocking transmission timing signal from the packet transmission / reception unit,
The transmission timing instructing function performs self-clocking for each of the plurality of packet transmission / reception units based on the self-clocking transmission timing signals generated by the plurality of packet transmission / reception units simultaneously used for communication with the communication partner. Measure the interval of the locking transmission timing signal, adjust the packet transmission timing of the plurality of packet transmission and reception unit to the interval of the longest self-clocking transmission timing signal based on the measurement result,
Computer program.

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