JP6429234B2 - Communication path control system and method - Google Patents

Description

  The present invention provides a network system in which a proxy server acting as an origin server, which is a content providing server, provides content to a terminal, and the terminal uses a plurality of wireless communication connection services to provide a plurality of mutually different The present invention relates to a technology for forming a communication path.

  Conventionally, there is a method of using a plurality of wireless communication connection services simultaneously. For example, the one described in Non-Patent Document 1 can process one communication simultaneously in parallel through a plurality of TCP (Transmission Control Protocol) communication paths, so that the terminal can perform LTE (Long Term Evolution) and Wi-Fi. By simultaneously using a plurality of different wireless communication connection services such as (Registered Trademark), communication can be continued even when Wi-Fi (Registered Trademark) is disconnected.

  On the other hand, there is a CDN (Contents Delivery Network) mechanism that shortens the logical communication distance (delay time, etc.) between the terminal and the server, reduces the load on the Internet backbone, and provides data to the terminal with low delay. doing. Non-patent document 2 describes that the terminal communicates with an IP address acquired by the terminal's wireless communication interface, which is different from the origin server that provides the content when the terminal resolves the DNS (Domain Name System) name. This is realized by a mechanism for acquiring and connecting the address of the communication proxy server (CDN content server) with the shortest distance.

  When using a plurality of wireless communication connection services, the server needs to support the simultaneous connection communication technology. Non-Patent Document 3 shows a method in which, when a server does not support the simultaneous connection communication function, a proxy server provided to the simultaneous connection communication function performs simultaneous connection communication and provides a simultaneous connection service.

  In the device described in Non-Patent Document 3, when the communication proxy server having the shortest communication distance for the IP address acquired by the wireless communication interface is compatible with the simultaneous connection communication technology, the terminal has a plurality of wireless communication interfaces. CDN communication using a communication connection service can be performed. On the other hand, if the communication proxy server with the shortest communication distance for the IP address acquired by the wireless communication interface does not support the simultaneous connection communication technology, the terminal can use another communication proxy that provides the simultaneous connection communication function. Through the server, it is possible to perform CDN communication using a plurality of wireless communication connection services.

A. Ford, 3 others, “TCP Extensions for Multipath Operation with Multiple Addresses”, RFC6824, Internet Engineering Task Force (IETF), January 2013 “Mechanism of CDN (Contents Delivery Network)” [online], JPO, [December 10, 2014 search], Internet <URL: http://www.jpo.go.jp/shiryou/s_sonota/hyoujun_gijutsu/ bidirectional_video / 152_1.htm> L. Deng and four others, “Use-cases and Requirements for MPTCP Proxy in ISP Networks”, draft-deng-mptcp-proxy-01, MPTCP Working Group, October 24, 2014

  When a terminal uses a wireless communication connection service including a plurality of mobile communications at the same time and communicates with a communication proxy server different from the origin server that provides Web contents, the terminal uses the wireless communication connection service used by the terminal. Communication proxy servers with short communication distances are different. Therefore, even if the wireless communication connection service connected to the communication proxy server with the shortest communication distance becomes unavailable, the communication proxy server remains an anchor point, and the communication distance is short for other wireless communication connection services. Since it is not a communication proxy server, there is a problem that inefficient communication with a large delay time and a large ISP (Internet Service Provider) transit amount occurs.

  For example, as shown in FIG. 21, when there are n wireless communication connection services, the wireless communication connection service n is connected to the proxy server 12 [n] having the shortest communication distance, and a plurality of wireless communication services are used simultaneously. think of. Here, when the wireless communication AP [n] provided by the wireless communication connection service n is disconnected, as shown in FIG. 22, communication is inefficient for the remaining remaining communication connection services.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to form an optimum communication path in a network system that simultaneously uses a plurality of wireless communication connection services and provides content by a proxy server. There is.

In order to achieve the above object, the present invention provides a first network that accommodates a first wireless access point for wide area wireless communication with a wide communication providing area and provides a connection service to the Internet for a terminal, and communication provision A second network that accommodates a second wireless access point related to local wireless communication with a small area and provides a connection service to the Internet for terminals, a content providing server that is deployed on the Internet, a first proxy server providing the content to the end edge on behalf of the content providing server, a communication path with a second proxy server that provides content to the end-terminal on behalf of the deployed content providing server in the second network A control system, a first wireless access point deployed in a first network A first access point information storage means for storing wireless communication service information in the second network, and a second access point information storage means for storing wireless communication service information in the second wireless access point provided in the second network. Application information storage means for storing application information related to a service provided by the content providing server; first wireless communication service information acquired from the first access point information storage means; and second wireless communication acquired from the second access point information storage means based on the service information and application information, the first wireless access point or the second wireless access point selected as the earliest destination, wireless access ports to the proxy server under the network housed wireless access point selected Forming a first communication path via the cement, then the e Bei communication control means for forming a second communication path via other wireless access point to the proxy server, is selected as the earliest destination In addition, content is provided to the terminal via the first communication path and the second communication path from the proxy server under the network in which the first wireless access point or the second wireless access point is accommodated .

  According to the present invention, it is possible to increase the amount of communication with a proxy server having a short communication distance by selecting a wireless communication connection service that is most likely to enable the terminal to perform communication most efficiently and performing simultaneous connection communication. Can do.

Configuration diagram of a network system according to an embodiment of the present invention Configuration diagram of a terminal according to an embodiment of the present invention An example of wireless communication service information Example of wireless communication service connection status information An example of application information The figure explaining operation | movement of the network system which concerns on embodiment of this invention The figure explaining operation | movement of the network system which concerns on embodiment of this invention A flowchart for explaining processing of a terminal related to acquisition of wireless communication service information Flowchart explaining terminal processing related to simultaneous connection processing Flowchart explaining terminal processing related to simultaneous connection processing The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. The flowchart explaining the process of the terminal which concerns on the simultaneous connection process which concerns on another example. Sequence chart explaining simultaneous connection processing Sequence chart explaining simultaneous connection processing The figure explaining operation | movement of the network system which concerns on the conventional embodiment The figure explaining operation | movement of the network system which concerns on the conventional embodiment

  A network system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of a network system according to the present embodiment.

  In the network system according to the present embodiment, as shown in FIG. 1, a plurality (n pieces; n is a natural number of 2 or more) of networks 10 are connected to the Internet. In the present application, in order to identify individual components of a component having a plurality of components of the same type such as the network 10 or the like, for example, an individual number is placed after the reference sign in parentheses, for example, the network 10 [1]. Add the items enclosed in brackets.

  In the Internet 100, an origin server 110, an origin server authority DNS server 120, and a CDN authority DNS server 130 are arranged.

  The origin server 110 holds and distributes the original content and provides the content to the terminal 1 via the proxy server 12 described later. The origin server 110 can also provide content directly to the terminal 1.

  The origin server authority DNS server 120 manages the host name and IP address of the origin server 110, and returns the IP address of the origin server 110 in response to a name resolution request from the DNS cache server described later. The origin server authoritative DNS server 120 has a function of transferring a name resolution request to the CDN authoritative DNS server 130 when the origin server 110 uses a CDN cache server (a proxy server 12 described later).

  In response to the name resolution request from the DNS cache server 11 described later, the CDN authoritative DNS server 130 returns the IP address of the proxy server 12 described later. Here, the CDN authoritative DNS server 130 communicates with the terminal 1 accommodated in the network 10 [i] (1 ≦ i ≦ n, the same applies hereinafter) to which the requesting DNS cache server 11 belongs in a network manner. The proxy server 12 having the shortest route (for example, having a short delay time) is selected, and the IP address of the proxy server 12 is returned to the request source.

  Each network 10 is a network managed by an ISP, and provides an Internet connection service to the terminal 1. Each network 10 assigns an IP address to the wireless communication interface of the terminal 1 in response to the connection request of the terminal 1, and enables the terminal to communicate with the other network 10 via the Internet 100 and the Internet 100.

  Each network 10 includes one or more DNS cache servers 11, one or more proxy servers 12, and one or more AP information management servers 13. Each network 10 accommodates one or more wireless access points AP and provides a wireless communication connection service to the terminal 1.

  The DNS cache server 11 receives the DNS query of the terminal 1, performs name resolution to the origin server authority DNS server 120 on behalf, and returns the result to the terminal 1. When the DNS query of the AP information management server 13 is received from the terminal 1, the IP address of the AP information management server 13 of the same network 10 to which the DNS cache server 11 belongs is returned.

  The proxy server 12 acquires content from the origin server 110 and provides the content to the terminal 1 on behalf of the origin server 120. The proxy server 12 may or may not have a cache function. In response to the content distribution request, the proxy server 12 having the cache function provides the retained content to the terminal 1 when the content server itself retains the content, while from the origin server 110 when not retaining the content. Acquired and provided to the terminal 1. The content may be retained by being cached when provided to the terminal 1, or may be acquired and retained from the origin server 110 in advance. The proxy server 12 having no cache function acquires content from the origin server 110 and provides the content to the terminal 1.

  In addition, the proxy server 12 forms a plurality of communication paths with a communication path that provides content to the terminal 1. Here, the plurality of communication paths pass through different networks 10. Formation of a plurality of communication paths is performed in response to a communication path establishment request from the terminal 1. An example of a protocol for forming a plurality of communication paths is MPTCP (MultiPath TCP).

  The AP information management server 13 acquires and holds the wireless communication service information about the wireless access point AP from each wireless access point AP belonging to each network 10, and stores the wireless communication service information in response to an inquiry from the terminal 1. return. Here, the wireless communication service information can include configuration information such as identification information of the wireless access point AP and identification information of the belonging network. Further, the wireless communication service information can include various statistical information regarding communication of the terminal 1 via the wireless access point AP. The statistical information may include information related to QoS, and may include, for example, an average connection time of terminals and throughput in the wireless access point AP.

  The wireless access point AP has a function of connecting the terminal 1 and the network 10 by connecting to the wireless communication interface of the terminal 1 by various wireless methods. The wireless method of the wireless access point AP is not limited, and may be a wireless method for connecting to a wide area wireless communication network with a wide communication providing area such as LTE or W-CDMA, or communication such as Wi-Fi (registered trademark). A wireless system for connecting to a local wireless communication network having a narrow provision area may be used. The wireless access point AP has a function of transmitting the above-described wireless communication service information to the terminal 1.

  As illustrated in FIG. 2, the terminal 1 includes a plurality of wireless communication interface units 2 that can be connected to each network 10 that provides various wireless communication services, and a wireless communication service information storage unit 3 that stores wireless communication service information. , A wireless communication service connection status storage unit 4 for storing connection statuses of various wireless communication services, an application information storage unit 5 for storing application information, a connection process to the network 10, and a communication path formation process to each server, etc. The communication control part 6 which performs etc. is provided.

  The wireless communication interface unit 2 uses a predetermined wireless communication method to execute communication connection processing to the wireless access point AP corresponding to the wireless communication method. The terminal 1 includes a wireless communication interface unit for connecting to a wide area wireless communication network having at least one communication providing area, and at least one wireless communication interface unit for a local wireless communication network having a narrow communication providing area. .

  The wireless communication service information storage unit 3 stores wireless communication service information about the network 10 that can be used by the terminal 1 in other words, that is, the network 10 in which the wireless access point AP currently in service is accommodated. The wireless communication service information is acquired from the AP information management server 13 belonging to the network 10 when the terminal 1 enters the communication area of the wireless access point AP and connects to the network 10. An example of the wireless communication service information is shown in FIG. In the example of FIG. 3, the wireless communication service information includes identification information (for example, BSSID (Basic Service Set ID) and cell ID) of the wireless access point AP, average terminal connection time μ (for example, seconds), throughput S ( The unit includes, for example, Byte / sec or bps) and identification information NW (for example, AS (Autonomous System) number) of the network 10 to which the unit belongs.

  The wireless communication service connection status storage unit 4 stores connection status information for the wireless access point AP to which the terminal 1 is currently connected, such as connection elapsed time. In the example of FIG. 4, the connection status information includes a connection elapsed time μe to the wireless access point AP.

  The application information storage unit 5 stores information on an application with which the terminal 1 communicates. The application information includes access destination information such as a name to be accessed by the terminal 1 in order to receive service provision by the application, and communication information such as communication data amount and communication time related to the service by the application. Note that the communication information may be for the entire service provision by the application, or may be limited to a specific service provision such as a specific content or a specific genre content. Further, the application information includes parameters of determination processing logic used in communication path formation processing by the communication control unit 6 described later, particularly determination parameter information such as a threshold value in the determination processing logic. In the example of FIG. 5, the application information includes the average connection time threshold Th of the terminal 1 and the access point connection elapsed time threshold Th_e as determination parameter information. The meaning of each parameter information will be described later.

  When connected to the network 10 via the wireless access point AP, the communication control unit 6 acquires wireless communication service information from the AP information management server 13 belonging to the network 10 and stores it in the wireless communication service information storage unit 3. At the same time, the connection status information is stored in the wireless communication service connection status storage unit 4. In addition, the communication control unit 6 performs a process for forming a plurality of communication paths based on the acquired wireless communication service information and application information, and if necessary, connection status information.

  In the present embodiment, the wireless access point AP [1] (corresponding to the first wireless access point in the claims) has a wide communication providing area such as LTE and W-CDMA and has sufficient wireless coverage (100%). It relates to a wide area wireless communication network, and it is assumed that the terminal 1 can always connect to the network 10 [1] via the wireless access point AP [1]. On the other hand, one or more other wireless access points AP [2] to [n] (each corresponding to the second wireless access point in the claims) have a narrow communication providing area such as Wi-Fi (registered trademark) and are wireless. It is related to a local wireless communication network with insufficient coverage, and wireless communication of the terminal 1 is interrupted with a certain probability. However, there is a difference in service contents such as usage fee, communicable data capacity, and communication speed between the wireless access point AP [1] and the wireless access points AP [2] to [n]. Therefore, conventionally, when both can be used, the terminal 1 sends traffic to the wireless access points AP [2] to [n] while the connection between the wireless access points AP [2] to [n] is disconnected. Only the process of flowing traffic to the wireless access point AP [1] was performed. In contrast, in the present invention, (a) the wireless access point AP [1] and the wireless access points AP [2] to [n] are simultaneously connected to form a plurality of communication paths, and (b) Communication path formation control is performed so that the anchor point becomes the proxy server 12 belonging to the network 10 that has the lowest disconnection probability. The operation of the present embodiment will be described below with reference to FIGS.

  Procedure 1: The terminal 1 connects to the wireless access point AP [i], obtains an IP address from the network 10 [i], and then inquires the AP information management server 13 [i] about the wireless communication service information [i]. Acquires and manages wireless communication service connection status information [i].

  Procedure 2: When the terminal 1 performs simultaneous connection communication, the terminal 1 determines a wireless access point AP to be initially connected from the wireless communication service information, the wireless communication service connection status information, and the application information.

  Procedure 3: The terminal 1 performs DNS name resolution using the wireless communication connection service related to the wireless access point AP determined in Procedure 2, and starts simultaneous connection communication with the proxy server 12. In the example of FIG. 6, the wireless access point AP [1] is determined and simultaneous connection to the proxy server 12 of the network 10 [1] is started.

  Procedure 4: A subflow is added from another wireless access point AP using the proxy server 12 connected in Procedure 3 as an anchor point for simultaneous connection.

  When the simultaneous connection process is performed in this way, even if the movement of the terminal 1 or the change in the communication status occurs, as shown in FIG. 7, the wireless connection service AP other than the wireless connection service AP selected in step 3 is used. Even if the connection is disconnected, there is a high possibility that the communication path is maintained for the wireless connection service AP selected in step 3. Therefore, it is possible to prevent the use of anchor points that are distant from the network, and efficient communication is possible.

  Next, a more detailed operation of the present embodiment will be described with reference to the drawings. FIG. 8 is a flowchart for explaining the wireless communication service information [i] acquisition process in the communication control unit 6. This flow 1 is performed every time the wireless communication interface unit 2 acquires an IP address.

  Next, the process procedure of the simultaneous connection process in the communication control unit 6, that is, the process of selecting the wireless access point AP and the procedure of forming a plurality of communication paths will be described with reference to FIGS. The flows 2-1-1, 1-1-2, 2-2-1, 2-2, 2-3-1, 2-2-2, and 2-4-2 shown in FIGS. The terminal 1 selects the wireless access points AP [2] to [n] that are most likely to perform simultaneous connection communication most efficiently. Any one of them may be adopted in carrying out the present invention.

  In the flow 2-1-1 shown in FIG. 9, first, the wireless communication service information and the application information are referred to, and the maximum value max (μ of the average terminal connection time μ for the plurality of wireless access points AP [2] to [n]. [I]) is calculated (steps S101 to S107). When the max (μ [i]) is larger than the average connection time threshold Th of the application information, the wireless access point AP [i] is set as the earliest connection destination (steps S108 and S109), and max (μ [i] If i]) is equal to or less than the average connection time threshold Th, the wireless access point AP [1] is set as the earliest connection destination (steps S108 and S110).

  A flow 2-1-2 illustrated in FIG. 10 is a modification of the flow 2-1-1. When max (μ [i]) is equal to or less than the average connection time threshold Th, a flow 3-1 described later is performed. The earliest connection destination is determined (steps S108 and S110 ′).

  The idea of the flow 2-1-X is to focus on the average terminal connection time μ in the wireless communication service information of the wireless access point AP, and compare this with the average connection time threshold Th to determine the earliest connection destination. To decide. The average connection time threshold value Th may be set to an optimum value through experiments or the like.

  In the flow 2-1-1 shown in FIG. 11, first, the wireless communication service information and the application information are referred to, and the communication data capacity D of the application information and the wireless communication service for the plurality of wireless access points AP [2] to [n] The minimum value min (D / 2 * S [i]) of the formula (D / 2 * S [i]) calculated from the information S [i] is calculated (steps S201 to S207). Next, when the average terminal connection time μ [i] is longer than min (D / 2 * S [i]), the wireless access point AP [i] is set as the earliest connection destination (steps S208 and S209), and μ When [i] is equal to or smaller than min (D / 2 * S [i]), the wireless access point AP [1] is set as the earliest connection destination (steps S209 and S210).

  A flow 2-2-2 illustrated in FIG. 12 is a modification of the flow 2-2-1. When μ [i] is equal to or smaller than min (D / 2 * S [i]), a flow 3 described later is performed. -1 determines the earliest connection destination (steps S208 and S210 ').

  In the flow 2-3-1 shown in FIG. 13, first, the wireless communication service information and application information are referred to, and the maximum value max (μ of the average terminal connection time μ for the plurality of wireless access points AP [2] to [n]. [I]) is calculated (steps S301 to S307). When the max (μ [i]) is larger than the equation (D / 2 * S [i]) calculated by the communication data capacity D of the application information and S [i] of the wireless communication service information, the wireless When the access point AP [i] is the earliest connection destination (steps S308 and S309), and max (μ [i]) is (D / 2 * S [i]) or less, the wireless access point AP [1] Is the earliest connection destination (steps S308 and S310).

  A flow 2-3-2 illustrated in FIG. 14 is a modification of the flow 2-3-1, and will be described later when max (μ [i]) is equal to or less than (D / 2 * S [i]). The earliest connection destination is determined by the flow 3-1 (steps S308 and S310 ′).

  The idea of the flow 2-2X and 2-3-3-X is to select a wireless access point AP with the largest traffic volume until communication is completed, and the average terminal connection time of the wireless access point AP. The earliest connection destination is determined based on μ, throughput S, and communication data capacity D. As a result, for example, a high-throughput Wi-Fi (registered trademark) such as WiGig can be selected as the earliest connection destination even if the average terminal connection time is short.

  In the flow 2-4-1 illustrated in FIG. 15, first, the wireless communication service information and application information are referred to, and the maximum value max (μ [I]) is calculated (steps S401 to S407). Then, the max (μ [i]) is larger than the equation T / 2 calculated by the scheduled communication time T of the application information, and the throughput S [i] of the wireless access point AP [i] is the communication of the application information. If it is equal to or greater than the formula (D / T) calculated from the scheduled time T and the communication data capacity D, the wireless access point AP [i] is set as the earliest connection destination (steps S408 and S409), otherwise Uses the wireless access point AP [1] as the earliest connection destination (steps S408 and S410).

  In the flow 2-4-2 shown in FIG. 16, instead of determining the wireless access point AP [1] (step S410), the earliest connection destination is determined by a flow 3-1 described later (step S410 ').

  The idea of the flow 2-4-X is determined by the average terminal connection time μ of the wireless access point AP and the scheduled communication time T of the application. This assumes a case where communication takes time without using the maximum throughput.

  Flows 3-1 and 3-2 shown in FIGS. 17 to 18 are performed when the terminal 1 stays in the connection area of the access point in order to intentionally use the specific wireless access point AP [i]. The wireless access point AP [i] is preferentially selected.

  In flow 3-1 shown in FIG. 17, the maximum value max (μe [i]) of the connection elapsed time μe is calculated for a plurality of wireless access points AP [2] to [n] with reference to the wireless communication service connection status. (Steps S501 to S507). When the max (μe [i]) is larger than the connection elapsed time threshold Th_e of the application information, the wireless access point AP [i] is set as the earliest connection destination (steps S508 and S509), and max (μ [ If i]) is equal to or less than the connection elapsed time threshold Th_e, the wireless access point AP [1] is set as the earliest connection destination (steps S508 and S510).

  A flow 3-2 illustrated in FIG. 18 is a modification of the flow 3-1, and when max (μe [i]) is equal to or less than the connection elapsed time threshold Th_e, the first flow is performed according to the flow 2-X-1. Is determined (steps S508 and S510 ′).

  Next, the simultaneous connection processing of the present embodiment will be described with reference to the sequence charts of FIGS. FIG. 19 shows an example in which a plurality of routes are formed with the wireless access point AP [1] as the earliest connection destination, and the proxy server 12 [1] under the network [1] is used as an anchor point.

  First, the terminal 1 connects to the wireless access point AP [2] and acquires the IP address A2 (step S801). Next, the terminal 1 resolves the name of the AP information management server 13 [2] to acquire the IP address B2-M of the AP information management server 13 [2] (steps S802 and S803), and the AP information management server 13 Wireless communication service information is acquired from [2] (steps S804 and S805). In steps S802 and S803, the IP address of the AP information management server 13 [2] is acquired by DNS. However, it may be acquired by an information distribution function of DHCP (Dynamic Host Configuration Protocol).

  Next, the terminal 1 determines the wireless access point AP [1] as the earliest connection destination (step S806).

  The terminal 1 resolves the name of the origin server 110 that is a content providing server (steps S807 to S810). What should be noted here is that the wireless access point AP [1] is selected as the earliest connection destination in step S806, so that the network that accommodates the wireless access point AP [1] as a DNS server for name resolution is used. [1] The subordinate DNS cache server 11 [1] is used. As a result, the DNS cache server 11 [1] transfers the DNS query to the CDN authoritative DNS server 130, acquires the IP address, and returns the acquired IP address to the terminal 1. Here, the IP address obtained by name resolution of the origin server 110 is the IP address B1 of the proxy server 12 [1] under the network [1].

  Then, the terminal 1 forms a plurality of communication paths by MPTCP with respect to the proxy server 12 [1] having the IP address B1. The communication path is formed by first forming the simultaneous connection connection # 1 via the wireless access point AP [1] (steps S811 to S814), and then the simultaneous connection connection # 2 via the wireless access point AP [2]. Are formed (steps S815 to S818).

  FIG. 20 shows an example in which a plurality of paths are formed with the wireless access point AP [2] as the earliest connection destination, and the proxy server 12 [2] under the network [2] is used as an anchor point.

  First, the terminal 1 connects to the wireless access point AP [2] and acquires the IP address A2 (step S901). Next, the terminal 1 resolves the name of the AP information management server 13 [2] to obtain the IP address B2-M of the AP information management server 13 [2] (steps S902 and S903), and the AP information management server 13 Wireless communication service information is acquired from [2] (steps S904 and S905). In steps S802 and S803, the IP address of the AP information management server 13 [2] is acquired by DNS, but may be acquired by the information distribution function of DHCP.

  Next, the terminal 1 determines the wireless access point AP [2] as the earliest connection destination (step S906).

  The terminal 1 resolves the name of the origin server 110 that is a content providing server (steps S907 to S910). What should be noted here is that the wireless access point AP [2] is selected as the earliest connection destination in the step S806, so that the network that accommodates the wireless access point AP [2] as a DNS server for name resolution. [2] The subordinate DNS cache server 11 [2] is used. As a result, the DNS cache server 11 [2] transfers the DNS query to the CDN authoritative DNS server 130, acquires the IP address, and returns the acquired IP address to the terminal 1. Here, the IP address obtained by name resolution of the origin server 110 is the IP address B2 of the proxy server 12 [2] under the network [2].

  Then, the terminal 1 forms a plurality of communication paths by MPTCP with respect to the proxy server 12 [2] having the IP address B2. The communication path is formed by first forming the simultaneous connection connection # 1 via the wireless access point AP [2] (steps S911 to S914), and then the simultaneous connection connection # 2 via the wireless access point AP [1]. Are formed (steps S915 to S918).

  As described in detail above, according to the network system according to the present embodiment, communication is performed by selecting a wireless communication connection service that is most likely to enable terminal 1 to perform communication most efficiently and performing simultaneous connection communication. The amount of communication with a proxy server with a short distance can be increased. Therefore, for example, in a state where LTE and a plurality of Wi-Fi wireless communication connection services can be used, a wireless communication connection service that is most likely to have the largest communication volume is selected, and simultaneous connection communication is performed. And transit costs can be reduced.

  Although the embodiment of the present invention has been described in detail above, the present invention is not limited to this. For example, the various protocols described in the above embodiments are merely examples, and the present invention can be implemented using other protocols. For example, although a plurality of communication paths are formed by MPTCP in the above-described mobile phone, communication paths may be formed by other protocols.

  DESCRIPTION OF SYMBOLS 1 ... Terminal, 10 ... Network, 11 ... DNS cache server, 12 ... Proxy server, 13 ... AP information management server, 100 ... Internet, 110 ... Origin server, 120 ... Origin server authority DNS server, 130 ... CDN authority DNS server

Claims (4)

A first network that accommodates a first wireless access point related to wide area wireless communication with a wide communication providing area and provides a terminal connection service to the Internet, and a second wireless access related to local wireless communication with a narrow communication providing area a second network that provides a connection service to accommodate the point to the Internet to the terminal, and the content providing server deployed in the Internet, the content to the end-terminal on behalf of the deployed content providing server in the first network a communication path control system comprising a first proxy server providing, a second proxy server that provides content to the end-terminal on behalf of the deployed content providing server in the second network,
A first access point information storage means for storing wireless communication service information in the first wireless access point provided in the first network; and a second access for storing wireless communication service information in the second wireless access point provided in the second network. Point information storage means,
The terminal stores application information storage means for storing application information related to a service provided by the content providing server, first wireless communication service information acquired from the first access point information storage means, and second access point information acquired from the second access point information storage means. 2 Based on the wireless communication service information and application information, the first wireless access point or the second wireless access point is selected as the earliest connection destination , and the proxy server under the network in which the selected wireless access point is accommodated is selected. forming a first communication path via the wireless access point, Bei example communication control means for forming a second communication path via other wireless access points for subsequent to said proxy server,
Providing content to the terminal via the first communication path and the second communication path from the proxy server under the network in which the first wireless access point or the second wireless access point selected as the earliest connection destination is accommodated A communication path control system. The communication control means resolves the address of the content providing server by the name resolution server under the network in which the first or second wireless access point selected as the earliest connection destination is accommodated, and sends it to the proxy server having the resolved address. The communication path control system according to claim 1, wherein a communication path is formed. The communication control means selects the first wireless access point or the second wireless access point under the network with the lowest disconnect probability as the earliest connection destination.
  The communication path control system according to claim 1 or 2, characterized by the above. A first network that accommodates a first wireless access point related to wide area wireless communication with a wide communication providing area and provides a terminal connection service to the Internet, and a second wireless access related to local wireless communication with a narrow communication providing area a second network that provides a connection service to accommodate the point to the Internet to the terminal, and the content providing server deployed in the Internet, the content to the end-terminal on behalf of the deployed content providing server in the first network a first proxy server and a second proxy server and the communication path control method in a network system having a providing a deployed content terminus on behalf of the content providing server in the second network to provide,
The network system includes a first access point information storage unit that is provided in the first network and stores wireless communication service information in the first wireless access point, and stores wireless communication service information that is provided in the second network and in the second wireless access point. Second access point information storage means for
The terminal includes application information storage means for storing application information related to the service provided by the content providing server, and the first wireless communication service information and the second access point acquired by the communication control means from the first access point information storage means. Based on the second wireless communication service information and application information acquired from the information storage means, the first wireless access point or the second wireless access point is selected as the earliest connection destination, and the network is subordinate to the selected wireless access point. Forming a first communication path via the wireless access point for the proxy server , and then forming a second communication path via another wireless access point for the proxy server ,
Providing content to the terminal via the first communication path and the second communication path from the proxy server under the network in which the first wireless access point or the second wireless access point selected as the earliest connection destination is accommodated A communication path control method.

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