KR101726357B1 - Method and apparatus for updating application list for multi-path packet data service - Google Patents

Abstract

The present invention provides a method for updating an application list for a multi-path packet data service and an apparatus therefor. The method of updating an application list for a multi-path packet data service in a multi-path control proxy server interworking with a terminal according to an embodiment of the present invention includes: receiving, by a multi-path service activation request message including terminal information from the terminal, The method comprising: transmitting a multi-path service activation response message including package information for identifying a multi-path service target application to the terminal; receiving a multi-path service status inquiry message including terminal information from the terminal; And transmitting the multi-path service status inquiry response message including the changed package information to the terminal when the package information is changed, as a result of the checking, whether or not the package information corresponding to the information is changed can do. Therefore, the present invention is advantageous in that the application list can be updated adaptively to provide multi-path packet data service.

Description

TECHNICAL FIELD [0001] The present invention relates to an application list updating method and apparatus for a multi-path packet data service,

The present invention relates to a multi-path packet data service, and more particularly, to a multi-path packet data service in which heterogeneous networks are integratedly managed using a multi-path control proxy server, To an application list updating method for a multi-path packet data service capable of providing a multi-path packet data service and an apparatus therefor.

The LTE (Long Term Evolution) network is divided into the LTE (E-UTRAN) related technologies and the EPC (Enhanced Packet Core) . Since the LTE network is an E2E all-IP network, all traffic flows from a wireless link that a user terminal connects to a base station to a packet data network (PDN) that connects to a final service provider operate on an IP basis.

When a user who has purchased an LTE terminal selects a service type and a fee plan when subscribing to a mobile communication service provider (hereinafter referred to as a "carrier") network, a provider configures a subscription profile based on the subscription information, And the like.

In particular, recent mobile communication terminals are equipped with a mobile communication function such as LTE as well as a short-range wireless communication function such as Wi-Fi. The user can activate or deactivate the LTE communication function and the Wi-Fi communication function through a menu selection of the mobile communication terminal.

That is, when a connection to a specific network is selected, a terminal supporting connection to a conventional heterogeneous network has blocked connection to the other network.

In addition, a conventional terminal capable of heterogeneous network connection is moved to a specific area (for example, home, office, and the like) in which wireless LAN communication such as Wi-Fi is available in a state where a data communication session of a mobile communication network such as LTE is established In one case, the ability to release an LTE data communication session and establish a data communication session by connecting to a wireless local area network was provided.

However, the data communication speed of the mobile communication network and the data communication speed of the wireless local area network may differ depending on the wireless environment at the connection time, and when automatic switching to the heterogeneous network due to the location movement, some services are disconnected or service quality is deteriorated There were disadvantages.

That is, conventionally, a method and apparatus for updating and managing a multi-path service target application list have not been provided.

It is therefore an object of the present invention to provide a method and an apparatus for updating an application list for a multipath packet data service.

It is another object of the present invention to provide a multi-path control proxy server that integrates and manages heterogeneous networks in order to provide an end-to-end service between a content server and a terminal, And to provide an apparatus therefor.

It is still another object of the present invention to provide a system and a recording medium that support the above methods.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

The present invention provides a method for updating an application list for a multi-path packet data service and an apparatus therefor.

The method of updating an application list for a multi-path packet data service in a multi-path control proxy server interworking with a terminal according to an embodiment of the present invention includes: receiving, by a multi-path service activation request message including terminal information from the terminal, The method comprising: transmitting a multi-path service activation response message including package information for identifying a multi-path service target application to the terminal; receiving a multi-path service status inquiry message including terminal information from the terminal; And transmitting the multi-path service status inquiry response message including the changed package information to the terminal when the package information is changed, as a result of the checking, whether or not the package information corresponding to the information is changed can do.

Here, the multipath service activation response message may further include state inquiry time information, and may receive the multipath service state inquiry request message from the terminal at a period corresponding to the state inquiry time information.

The method of updating an application list for a multi-path packet data service may further include receiving the non-periodic multi-path service status inquiry request message from the terminal, wherein the non-periodic multi-path service status inquiry message And may be received when a specific terminal event is generated in the terminal.

Here, the specific terminal event may include an event in which the IP address of the terminal is changed.

At this time, the event that the IP address of the terminal is changed may include at least one of an access / disconnection event, an activation / deactivation event of the airplane mode, and a reboot event in the mobile communication network or the local area wireless communication network.

Also, the mobile communication network may include at least one of an LTE (Long Term Evolution) network and an LTE-Advanced network, and the short-range wireless communication network may include a Wi-Fi network.

The method may further include determining whether the multi-path packet data service can be provided to the terminal when the multi-path service status inquiry message is received, May be further included in the multipath service status query response message.

In addition, the package information may include information for identifying a multi-path service target application list corresponding to the terminal information.

Here, the package information may include a predefined package name for each application included in the application list.

Here, the package name may include at least one of service provider information, application manufacturer information, OS type identification information, and unique application identification information.

Receiving a TCP (Transmission Control Protocol) packet generated by an application corresponding to the package information from an application server through a first TCP session; and transmitting the received TCP packet to a first TCP through a second TCP And distributing the sub-flow session to the sub-flow session.

Receiving the TCP packet generated in the application corresponding to the package information from the terminal through the first and second TCP subflow sessions; and transmitting the TCP packet received through the first and second TCP subflow sessions, And transmitting the merged packet to the application server through the first TCP session.

Also, the first TCP session may be a TCP session established between the application server and the multi-path control proxy server via the Internet.

The first and second TCP sub-flow sessions may include a TCP session established between the multi-path control proxy server and the terminal via the mobile communication network, and a short-range wireless communication network between the multi-path control proxy server and the terminal It can include a configured TCP session.

The status query time may be determined based on at least one of a load and a failure status of the multi-path control proxy server, a network failure between the terminal and the multi-path control proxy server, and a load status.

Also, the terminal information may include at least one of International Mobile Subscriber Identification (IMSI) information, MSISDN (Mobile Station International ISDN Number) information, terminal IP information, and terminal model name information.

In another aspect of the present invention, there is provided a method of updating an application list for a multi-path packet data service in a terminal interworking with a multi-path control proxy server, the method comprising: From the multipath control proxy server, a multipath service activation response message including first package information and status query time information for identifying the multipath service target application, And transmitting the multi-path service status inquiry request message including the terminal information to the multi-path control proxy server periodically.

The method may further include, when a specific terminal event is detected, transmitting the multi-path service status inquiry request message to the multi-path control proxy server.

Here, the specific terminal event may be an event that is detected when the IP address of the terminal changes.

Here, the event that the IP address of the terminal is changed may include at least one of an access / disconnection event, an activation / deactivation event of the airplane mode, and a reboot event in the mobile communication network or the short-range wireless communication network.

Also, the method of updating an application list for a multi-path packet data service in the terminal may include receiving a multi-path service status query response message including second package information, and updating the first package information with the second package information Step < / RTI >

The multi-path service status inquiry message may further include information on whether the multi-path service can be provided. If it is determined that the multi-path service can not be provided, the multi-path service status inquiry message Transmission can be blocked.

One embodiment of the present invention can provide a recording medium on which a program for executing any one of the multipath control proxy server and the application list updating methods for the multipath packet data service in the terminal is recorded .

According to an embodiment of the present invention, a multi-path control proxy server providing a multi-path packet data service in cooperation with a terminal may receive a multi-path service activation request message including terminal information from the terminal, Means for receiving a multi-path service status inquiry message including terminal information from the terminal, means for receiving a multi-path service status inquiry message including package information for identifying the terminal, Means for checking whether the package information has been changed; and means for transmitting, to the terminal, a multipath service status query response message including the changed package information when the package information is changed as a result of the checking.

A terminal for providing a multi-path packet data service in cooperation with a multi-path control proxy server according to an embodiment of the present invention includes means for transmitting a multi-path service activation request message to the multi-path control proxy server according to a user menu selection, Means for receiving a multi-path service activation response message including first package information and status query time information for identifying a multi-path service target application from the multi-path control proxy server; And means for periodically transmitting the included multipath service status query request message to the multipath control proxy server.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And can be understood and understood.

Effects of the method and apparatus according to the present invention will be described as follows.

An advantage of the present invention is to provide a method and apparatus for updating an application list for a multi-path packet data service.

It is another object of the present invention to provide a multi-path control proxy server that integrates and manages heterogeneous networks in order to provide an end-to-end service between a content server and a terminal, And to provide an apparatus therefor.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. It is to be understood, however, that the technical features of the present invention are not limited to the specific drawings, and the features disclosed in the drawings may be combined with each other to constitute a new embodiment.
1 is a block diagram of an LTE network for facilitating understanding of the present invention.
FIG. 2 is a view for explaining traffic flows on an LTE network for facilitating understanding of the present invention. FIG.
3 is a diagram for explaining an IP address assignment method in an LTE network for facilitating understanding of the present invention.
FIG. 4 is a diagram for explaining an IP address assignment procedure to help understand the present invention.
5 is a block diagram of a multi-path service providing system according to an embodiment of the present invention.
6 is a configuration diagram of a multi-path service providing system according to another embodiment of the present invention.
7 is a diagram for explaining a multipath service authentication procedure according to an embodiment of the present invention.
8 is a diagram for explaining a multipath service providing procedure according to an embodiment of the present invention.
9 to 10 are views for explaining a multi-path service control flow and a user interface screen in a terminal according to an embodiment of the present invention.
11 is a flowchart illustrating a signaling procedure for setting and canceling a multipath service according to an embodiment of the present invention.
12 is a flowchart illustrating a method of updating an application list for a multi-path packet data service according to an embodiment of the present invention.
13 is a flowchart illustrating a method of updating an application list for a multi-path packet data service according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus and various methods to which embodiments of the present invention are applied will be described in detail with reference to the drawings. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

1 is a configuration diagram of an LTE network according to the present invention.

1, an LTE network includes a UE (User Equipment) 10, an Evolved Node B (eNB) 20, an S-GW (Serving Gateway) 30, a Packet Data Network Gateway An MCS (Mobility Management Entity) 50, an HSS (Home Subscriber Server) 60, an SPR (Subscriber Profile Repository) 70, an OFFCS (Offline Charging System) 80, an OCS (Online Charging System) (Policy and Charging Rule Function, 100).

 The UE 10 is an LTE user terminal and is connected to the LTE Uu interface 15 with the eNB 20. Here, the LTE Uu interface 15 defines a control plane for transmitting and receiving a control message as a wireless interface and a user plane for providing user data.

The eNB 20 provides a radio interface to the UE 10 and provides radio resource management functions such as radio bearer control, radio admission control, dynamic radio resource allocation, load balancing and inter-cell interference control do.

The S-GW 30 is an end point of an evolved universal terrestrial radio access network (E-UTRAN) and an evolved packet core (EPC), and an anchor point at handover between the eNB 20 and the 3GPP system do. The E-UTRAN comprises at least one eNB 20, and the EPC comprises an S-GW 30, a P-GW 40 and an MME 50.

The P-GW 40 connects the UE 10 to an external PDN (Packet Data Network) 110 and performs a packet filtering function. In addition, the P-GW 40 assigns an IP address to the UE 10 and operates as a mobility anchoring point when performing handover between the 3GPP system and the non-3GPP system. In particular, the P-GW 40 receives the Policy and Charging Control (PCC) rule from the PCRF 100, applies it to the corresponding service flow, and provides the billing function per UE 10 / SDF (Service Date Flow) do.

The HSS 60 provides a user profile and a user profile to the MME 50 as a database of subscriber profiles.

The SPR 70 provides subscriber and subscription related information to the PCRF 100, and the PCRF 100 generates subscriber based PCC rules using the subscriber and subscription related information.

OFCS 80 provides charging information based on CDR (Charging Data Record).

OCS 90 provides volume, time, and event-based billing functions through real-time credit control.

The PCRF 100 provides policy control decisions and billing control functions as entities that perform policy and billing control. The PCC rules generated in the PCRF 100 are transmitted to the P-GW 40.

Hereinafter, the interface between the elements constituting the LTE network will be briefly described.

The LTE-Uu 15 provides a control plane and a user plane with a radio interface between the UE 10 and the eNB 20. [

The S1-U 25 is an interface between the eNB 20 and the S-GW 30, and provides a user plane. At this time, GTP tunneling per bearer is provided.

S5 35 is an interface between the S-GW 30 and the P-GW 40, providing a control plane and a user plane. At this time, the user plane provides bearer-specific GTP tunneling, and the control plane provides GTP tunnel management.

SGi 45 defines a user plane and a control plane as an interface between the P-GW 40 and the PDN 110. In the user plane, IETF based IP packet forwarding protocol is used, and in the control plane, protocols such as DHCP and RADIUS / Diameter are used.

S11 55 defines a control plane as an interface between the MME 50 and the S-GW 30, and GTP tunneling per bearer is provided.

X2 65 is an interface between the two eNBs 20, providing a control plane and a user plane. The X2-AP protocol is used in the control plane and the GPRS tunneling protocol (GTP) per bearer for data forwarding in the X2 handover in the user plane.

S6a (75) is provided with a control plane as an interface between the HSS 60 and the MME 50, and is used for exchanging UE subscription information and authentication information.

The Gx 85 is an interface between the PCRF 100 and the P-GW 40. The control plane is defined and used to convey policy control rules and billing rules for QoS (quality of service) policy and billing control .

Sp (95) is an interface between the SPR 70 and the PCRF 100, in which a control plane is defined and used to convey a user profile.

Gz 105 is an interface between the OFCS 80 and the P-GW 40 and defines a control plane and is used for CDR transmission from the P-GW 40 to the OFCS 80. [

Gy 115 is an interface between the OCS 90 and the P-GW 40. The control plane is defined and used for real-time credit control information exchange.

FIG. 2 is a view for explaining traffic flows on an LTE network for facilitating understanding of the present invention. FIG.

More specifically, Figure 2 shows the Internet traffic flow in the user plane of the LTE network reference model. Reference numeral 200a denotes a traffic flow from the UE 10 to the Internet, hereinafter referred to as "uplink traffic flow", 200b denotes a traffic flow from the Internet to the UE 10, hereinafter referred to as " Business card.

IP packets are transmitted over the GTP tunnel on the S1-U (25) and S5 (35) interfaces, respectively. Here, the GTP tunnel is set for each EPS bearer through control signaling when the UE 10 initially connects to the LTE network.

Since several EPS bearers are set on one of the S1-U 25 and the S5 (35) interfaces, a tunnel endpoint identifier (TEID) is allocated upwardly and downwardly in each GTP tunnel establishment to distinguish them. When a GTP tunnel is set in the S1-U (25) interface, a TEID (UL S1-TEID) having an end point is allocated to the S-GW 20 upward and a TEID (DL S1-TEID) having an end point is allocated to the eNB 20 -TEID). Similarly, when a GTP tunnel is established in the S5 (35) interface, a TEID (UL S5-TEID) having an end point in the P-GW 40 and a TEID (DL S5-TEID) having an end point in the S- S5-TEID).

The eNB 20, the S-GW 30 and the P-GW 40 transmit a GTP tunnel header to the GTP packet header when the user IP packet is transmitted through the GTP tunnel on the S1-U 25 and the S5 When it is generated, it inserts the allocated TEID and transmits it. The S-GW 30 must have mapping information between the UL S1-TEID and the UL S5-TEID in order to terminate the S1-GTP tunnel in the upward direction and to transmit the user IP packet to the S5-GTP tunnel. Likewise, in the downlink, mapping information between DL S5-TEID and DL S1-TEID must be maintained.

Hereinafter, referring to FIG. 2, a procedure for each entity to process uplink and downlink Internet traffic flows will be described in detail.

First, in the uplink, the UE 10 transmits internally generated user IP packets to the eNB 20 via the LTE-Uu 15 interface. The eNB 20 constructs an S1 GTP header having the S-GW IP address as the destination address, the eNB 20 address as the originating address, the UL S1-TEID as the TEID, and adds the S1 GTP header to the received user IP packet. To the S-GW 30.

When receiving the user IP packet through the S1 GTP tunnel, the S-GW 30 transmits the IP address of the P-GW 40 to the destination address, the S-GW 30 to the originating address, and the UL S5-TEID to the S5 Configure the GTP header. Then, the S5 GTP header is added to the user IP packet and transmitted to the P-GW 40 through the S5 GTP tunnel.

Subsequently, the P-GW 40 controls the S5 GTP header to extract user IP packets, and then transmits them to the Internet through IP routing.

Referring to the downlink traffic flow, the P-GW 40 receives a user IP packet directed to the UE 10 via the Internet. The P-GW 40 adds the S5 GTP header having the S-GW IP address as the destination address, the P-GW IP address as the sending address and the DL S5-TEID as the TEID to the user IP packet, To the S-GW 30.

The S-GW 30 adds the eNB IP address to the destination IP address, the source address of the S-GW IP address, and the S1 GTP header including the DL S1-TEID with the TEID to the user IP packet received through the S5 GTP tunnel, To the eNB 20 via the GTP tunnel.

The eNB 20 transmits the user IP packet from which the S1 GTP header has been removed to the UE 10 via a data radio bearer (DRB), which is a bearer on the radio link.

It should be noted that the GTP tunnel shown in FIG. 2 is a user plane GTP tunnel for transmitting a user IP packet, hereinafter referred to as a "GTP-U tunnel ".

3 is a diagram for explaining an IP address assignment method in an LTE network for facilitating understanding of the present invention. More specifically, FIG. 2 illustrates a method for allocating an IP address to a user terminal in a LTE network when a user terminal accesses an LTE network in the LTE network. The method includes a Dynamic IP Address Allocation ) Method and a static IP address allocation method.

Generally, the UE 10 requests a connection of the PDN 110 to the LTE network upon initial connection to the LTE network. The P-GW 40 assigns an IP address - that is, a PDN address - to be used by the UE 10 to provide the PDN 110 connection to the UE 10 and delivers it to the UE 10. Here, the PDN address is transmitted from the P-GW 40 to the UE 10 in the process of setting a default bearer between the P-GW 40 and the UE 10, and the UE 10 transmits the PDN The PDN 110 can access the service provided by the PDN 110 using the address.

The P-GW 40 allocates an IP address to the UE 10 by a dynamic IP address allocation method that is dynamically generated each time the UE 10 accesses the LTE network, There is a fixed IP address assignment method in which the subscriber profile stored in the HSS 60 is referred to when the UE 10 connects to the LTE network.

More specifically, as shown in FIG. 3, when a UE accesses an LTE network after a provider configures an IP pool in the P-GW 40 in advance, And assigns an IP address dynamically.

On the other hand, in the fixed IP address assignment method, when a user joins a service provider network, a service provider allocates an IP address to be permanently used to the UE 10 and maintains the IP address in the HSS 60. When the UE 10 accesses the LTE network, The GW 40 receives the IP address corresponding to the UE 10 from the HSS 60 and delivers the IP address to the UE 10. [

The UE 10 may request predetermined protocol information related to an external protocol and an application using a Protocol Configuration Option (PCO) parameter in a process of requesting a PDN connection when initially accessing an LTE network. Here, the protocol information may include a DNS server address.

The details of the above-mentioned PCO will be described in detail in 3GPP TS 24.008.

FIG. 4 is a diagram for explaining an IP address assignment procedure to help understand the present invention. More specifically, FIG. 4 is a diagram for explaining a static IP address assignment procedure.

Referring to FIG. 4, the UE 10 transmits a PDN Connectivity Request message to the MME 50 when the UE 10 is powered on (S401). At this time, the PDN connection request message may include information such as International Mobile Station Identity (IMSI), PDN type = IPv4, and PCO = DNS Server IPv4 Address Request. Here, IMSI is unique identification information for identifying a subscriber in the LTE network.

The MME 50 transmits a Location Update Request message including the IMSI to the HSS 60 (S403)

The HSS 60 inquires of the subscriber profile corresponding to the IMSI from the internal database and transmits to the MME 50 a Location Update Answer Message including a fixed IP address allocated in advance to the corresponding subscriber (S405) .

The MME 50 includes a session creation request including a fixed IP address received from the HSS 60 and an International Mobile Subscriber Identity (IMSI) received from the UE 10, PDN type = IPv4, PCO = DNS Server IPv4 Address Request, (Create Session Request Message) to the S-GW 30 (S407).

Subsequently, the S-GW 30 transmits the received session creation request message to the P-GW 40 (S409).

Thereafter, in response to the request message in steps 409 and 407, the P-GW 40 and the S-GW 30 send a Create Session Response message to the MME 50 send. Here, the session creation response message may include the fixed IP address in the PDN address field and the DNS server IP address requested by the user in the PCO field.

The MME 50 transmits an Activate Default EPS Bearer Context Request message including a static IP address and a DNS IP address, wherein the DNS IP address may include a primary DNS IP address and a secondary DNS IP address. To the UE 10 (S415). Here, the default EPS bearer activation request message, which is one of the EPS session management messages (hereinafter referred to as "ESM (EPS Session Management) messages"), is an EPS mobility management message. May be included in the "Attach Accept Message" called "EMM (EPS Mobility Management) message".

Thereafter, a static IP address and a DNS IP address are stored in the internal memory of the UE 10 (S417), and a default EPS bearer is set between the UE 10 and the P-SW 40 (S419). At this time, the UE 10 can access the PDN 110 through the set default EPS bearer and transmit / receive user IP packets.

Hereinafter, policy and accounting control in an LTE network will be briefly described.

The PCRF 100 determines the PCC rules for each service data flow (SDF) and transmits the determined PCC rules to the PCF (Policy and Charging Enforcement Function) (for example, P-GW 40). Here, the PCC rule can be determined based on a provider policy - for example, QoS policy, gate status, billing method, and the like. The PCC rules may also include information on detection of packets belonging to a particular SDF, identification of the service, accounting parameters to be applied to the SDF, and policy control on the SDF.

The PCRF 100 generates a predetermined packet filter (e.g., SDF template) for detecting which SDF the user IP packets transmitted and received on the SGi 45 interface correspond to, Can be applied to rules. In addition, the P-GW 40 may bind the SDF QoS and the LTE bearer QoS using the PCC rules received from the PCRF 100, and then reflect the SDF QoS and the LTE bearer QoS on the EPS bearer.

Here, the SDF template is included in the above PCC rule. The SDF template consists of a source IP address, a destination IP address, a source port, a destination port, and a protocol identifier for each of the uplink and the downlink. Is a 5-tuple based SDF delimiter (Classifire).

In general, there may be a plurality of IP flows or a "Service Flow" depending on the application service used by one UE or depending on the type of traffic transmitted and received. For example, an application service may include a Naver connection, a next connection, a Kakao Talk, a game, VoIP, YouTube, and the like. These IP flows can be mapped to SDF using a 5-tuple-based SDF template. As described above, when a plurality of IP flows are classified into 5-tuple-based SDFs, the P-GW 40 can process the QoS for each SDF and map the corresponding SDF to the EPS bearer.

5 is a block diagram of a multi-path service providing system according to an embodiment of the present invention.

5, the multipath service providing system may include an application server 510, a terminal 520, an Internet network 530, a mobile communication network 540, and a local area wireless communication network 550. The configuration of the multipath service providing system shown in FIG. 5 is not necessarily an essential configuration, and may have more or fewer components.

The application server 510 may be divided into an application layer 511, a multipath control layer 512, and a TCP subflow layer 513. Here, the TCP sub-flow layer 513 may include a first TCP sub-flow 513-1 and a second TCP sub-flow 513-2, but this is only one embodiment, and the application server 510 ) Are interworking with more different wireless networks, it should be noted that more TCP sub-flows may be provided. For example, the first TCP subflow 513-1 provides a function of transmitting and receiving a TCP packet with the terminal 520 through a first TCP subflow session via a mobile communication network 540 such as LTE / LTE-A And the second TCP subflow 513-2 may provide a function of transmitting and receiving a TCP packet with the terminal 520 through a second TCP subflow session via a local wireless communication network 550 such as Wi-Fi have

The application layer 511 is a layer for providing various application services or application contents. For example, the application layer 511 may include, but is not limited to, a live streaming service such as an HDTV service, a file download service such as a movie download, a file upload service, a game service, a chat service,

The TCP packet generated in the application layer 511 is transmitted to the multi-path control layer 512. When the multipath service is activated between the application server 510 and the terminal 520, the multi-path control layer 512 distributes the received TCP packet from the application layer 511 to the first TCP subflow 513 -1) to the second TCP subflow 513-2.

5, the TCP packet transmitted by the first TCP subflow 513-1 is transmitted to the first TCP subflow 523-i of the terminal 520 via the Internet 530 and the mobile communication network 540, 1 < / RTI > The TCP packet transmitted by the second TCP subflow 513-2 is transmitted to the second TCP subflow 523-2 of the terminal 520 via the Internet 530 and the local area wireless communication network 550 Lt; / RTI >

That is, the first TCP subflow 513-1 of the application server 510 and the first TCP subflow 523-1 of the terminal 520 are connected to each other through the Internet 530 and the mobile communication network 540 And the second TCP subflow 513-2 of the application server 510 and the second TCP subflow 523-2 of the terminal 520 are connected to the Internet 530 and the wireless local area network 550, End-to-end communication can be performed.

The multi-path control layer 522 of the UE 520 may merge the TCP packets received from the first TCP subflow 513-1 and the second TCP subflow 513-2 and forward them to the application layer 521 have.

In the above description, the TCP packet transmission procedure according to the multipath service from the application server 510 to the terminal 520 has been described in detail, but the TCP packet transmission procedure according to the multipath service from the terminal 520 to the application server 510 Therefore, detailed description will be omitted.

5, since the multi-path control function is installed at the application server 510, it is required not only to improve the functions of all the application servers 510 but also to apply the multi-path control to all the application servers 510 It is difficult to adaptively control the multi-path service according to the kind of the application service and the subscriber of the mobile communication service, for example, the subscription fee of the mobile communication service subscriber.

6 is a configuration diagram of a multi-path service providing system according to another embodiment of the present invention.

6, the multi-path service providing system includes an application server 610, a multi-path control proxy server 620, a terminal 630, an Internet network 640, a mobile communication network 650 And a short-range wireless communication network 660. The configuration of the multipath service providing system shown in FIG. 6 is not necessarily an essential configuration, and may have more or fewer components.

The application server 610 may include an application layer 611 and a TCP layer 612. It should be understood by those skilled in the art that the application server 610 may include more layers than the application layer 611 and the TCP layer 612 for convenience of description.

The multipath control proxy server 620 may be configured to include a TCP layer 621, a multipath control layer 622 and a TCP subflow layer 623, As will be apparent to those skilled in the art. For example, the multi-path control proxy server 620 may be associated with an external policy management server (not shown) and may obtain policy change information from an external policy management server. Here, the policy change information may include, but is not limited to, change information of an application list capable of multipath services and information on a package name per application included in the changed application list.

The multi-path control proxy server 620 may update the multi-path service target application list stored in the predetermined recording area according to the received policy change information.

When a multipath service authentication request message to be described later is received from the terminal 630, a multipath service activation request message is received, or a multipath service status inquiry request message is received from the terminal 630, the multipath control proxy server 620 updates The package name corresponding to the application list can be extracted and transmitted to the terminal 630.

Accordingly, through the update procedure of the multi-path service application list, the terminal 630 can quickly identify whether the multi-path service is available and the multi-path service target application list, and also can quickly There are advantages to apply.

The terminal 630 may include an application layer 631, a multipath control layer 632, and a TCP subflow layer 633, but this is for the sake of convenience only, It will be apparent to those skilled in the art that the present invention may be embodied in other forms.

Hereinafter, a procedure for providing an end-to-end packet data service between the application server 610 and the terminal 630 will be described in detail with reference to FIG.

The TCP packet generated in the application layer 611 of the application server 610 is transmitted to the TCP layer 612 of the application server 610 and the TCP layer 612 of the application server 610 transmits the Internet network 640 To the TCP layer 621 of the multi-path control proxy server 620, the TCP packet received from the application layer 611 of the application server 610 using the TCP session established through the TCP session. Subsequently, when the TCP layer 621 of the multipath control proxy server 620 forwards the received TCP packets to the multipath control layer 622 of the multipath control proxy server 620, the multipath control layer 622 The received TCP packet can be distributed to the first TCP subflow 623-1 and the second TCP subflow 623-2 of the TCP subflow layer 623 and transmitted. Here, the multi-path control layer 622 dynamically allocates the first TCP to the first TCP subflow session based on the session state information collected corresponding to the first and second TCP subflow sessions established through the mobile communication network 650 and the local area wireless communication network 660, It is possible to determine the distribution ratio of the received TCP packet to be transmitted to the sub-flow 623-1 and the second TCP sub-flow 623-2.

For example, the session state information may include at least one of the available bandwidth information, the transmission delay information, the average transmission rate information per unit time, and the packet data transmission error rate collected in the wired section and the wireless section of each of the first and second TCP sub- But is not limited thereto.

The TCP packet transmitted by the first TCP subflow 623-1 is transmitted to the first TCP subflow 633-1 of the TCP subflow layer 633 of the terminal 630 via the mobile communication network 650 . The TCP packet transmitted by the second TCP subflow 623-2 is transmitted to the second TCP subflow 633-2 of the terminal 630 and the TCP subflow layer 633 via the local area wireless communication network 660, Lt; / RTI >

The first TCP sub-flow 633-1 and the second TCP sub-flow 633-2 transmit the received TCP packet to the multi-path control layer 632 of the terminal 630, Can sort the received TCP packets in the order transmitted by the application server 610 and transmit them to the application layer 631. [ For this purpose, the TCP packet may include a predetermined sequence number indicating the transmission order.

A method of transmitting the TCP packet generated in the application server 610 to the terminal 630 via the multipath (the mobile communication network 650 and the local area wireless communication network 660) via the multipath control proxy server 620 And the device configuration related thereto are described in detail, the TCP packet generated in the application layer 631 of the terminal 630 is transmitted to the application server 610 via the multipath control proxy server 620 through the multipath Method and device configurations related thereto are similar to each other, and therefore, a detailed description thereof will be omitted.

However, the multi-path control layer 632 of the terminal 630 may also collect session state information corresponding to the first and second TCP sub-flow sessions established through the mobile communication network 650 and the local area wireless communication network 660 And determine a distribution ratio of TCP packets to be delivered to the first TCP subflow 633-1 and the second TCP subflow 633-2 based on the collected session state information. It should be noted that the TCP packet is a TCP packet generated by an application capable of multipath service.

For example, the session state information collected by the multipath control layer 632 of the terminal 632 may include available bandwidth information, transmission delay information, and the like, which are collected in the wireless section and the wire section of each of the first and second TCP sub- An average transmission rate information during a unit time, and a packet data transmission error rate. However, the present invention is not limited thereto.

In the multipath service providing system of FIG. 6, when all the TCP packets transmitted between the application server 610 and the terminal 630 pass through the multi-path control proxy server 620, the multi-path control proxy server 620 transmits, A heavy load may be generated in the multi-path control proxy server 620. To solve this problem, it may be required to improve the performance and capacity of the multi-path control proxy server 620. [ Therefore, the system construction cost due to the provision of the multi-path service can be increased.

One embodiment of the present invention is a method for solving the above problem, wherein the multi-path control proxy server 620 or the terminal 630 adaptively provides a multi-path service based on a type of a service target application Or by providing a single path service, unnecessary resource waste and overload can be prevented from occurring in advance.

In particular, the terminal 630 according to an exemplary embodiment of the present invention may periodically transmit a multi-path service status inquiry request message to the multi-path control proxy server 620. The period during which the terminal 630 transmits the multi-path service status inquiry request message includes a status query time defined in the body 1220 area of the multi-path service activation response message 1200 of FIG. 12, Can be determined based on information.

In accordance with an embodiment of the present invention, the multipath control proxy server 620 may dynamically change the status query time to control the reception period of the multipath service status query message whenever a multipath service activation request message is received have.

As an example, the multipath control proxy server 620 may adaptively determine the state query time based on internal load state and internal fault state, network fault state, and network load state. Here, the network load state is determined by the network load state of the TCP session established between the multipath control proxy server 620 and the application server 610, the state of the network load state between the multipath control proxy server 620 and the terminal 630 The network load state of the TCP session through the local wireless communication network set up between the multipath control proxy server 620 and the terminal 630, and the network load state of the TCP session via the local wireless communication network.

If the internal load is equal to or higher than the reference value or the network load state is equal to or higher than the reference value, the multipath control proxy server 620 determines the state query time so as to increase the reception period of the multipath service state query message. Conversely, The state query time may be determined such that the reception period of the multipath service state query message is shortened, but the present invention is not limited thereto.

The terminal 630 according to another embodiment of the present invention may transmit a multi-path service status inquiry message to the multi-path control proxy server 620 when a specific terminal event is detected.

Here, the specific terminal event may include an access or disconnection event, an activation or deactivation event of the airplane mode, a reboot event, and the like to or from the mobile communication network or the local area wireless communication network. However, It can be determined that a specific terminal event for transmitting the multi-path service status inquiry message is generated.

Hereinafter, a method of adaptively controlling a multipath service according to a service target application type will be described in detail.

7 is a diagram for explaining a multipath service authentication procedure according to an embodiment of the present invention.

7, when a predetermined menu selection for activating the multi-path service is detected on the user interface screen of the terminal 710, the terminal 710 transmits the multi-path service authentication request message including the terminal information to the multi- To the server 720 (S701).

 The multi-path control proxy server 720 may transmit a predetermined authentication request message including the received terminal information to the home subscriber server 730 in order to check whether the terminal requesting authentication is a multi-path service target terminal (S702).

The home subscriber server 730 may inquire the subscriber information database for the key value of the received terminal information and determine whether the corresponding terminal 710 is a multipath service provision target terminal in step S703.

The home subscriber server 730 may transmit a predetermined authentication response message indicating that the corresponding terminal 710 is a multipath service target terminal to the multipath control proxy server 720 (S704) .

The multi-path control proxy server 720 identifies an application list capable of multi-path service and extracts package information corresponding to the identified application list (e.g., package name) (S705). For example, the package name may be configured with information such as OS type information on which the application is mounted (including, for example, Android, iOS, etc.), and a unique application identifier defined to uniquely identify an application corresponding to the OS type But it is not limited thereto, and the application can be uniquely identified on the multipath control proxy server and the terminal.

The multi-path control proxy server 720 may transmit the multi-path service response message including the extracted package information or the package name to the terminal 710 (S706).

The terminal 710 may update package information for identifying an application capable of multipath service according to the received package information or the package name (S707).

The terminal 710 outputs a guide message indicating that the multi-path service is activated and can set the multi-path service selection menu to ON (S707).

8 is a diagram for explaining a multipath service providing procedure according to an embodiment of the present invention.

Referring to FIG. 8, the terminal 820 may transmit a multi-path service activation request message including terminal information to the multi-path control proxy server 830 (S801).

The multi-path control proxy server 830 identifies the multi-path service target application list corresponding to the terminal information, and extracts the registered package name for each application included in the applicable application list (S802 to S803). Here, the application-specific package name may be recorded in a predefined application / package name mapping table and maintained in the terminal 820 and the multipath control proxy server 830.

The multi-path control proxy server 830 may transmit the multi-path service activation response message including the extracted package name to the terminal 820 (S804). At this time, the terminal 820 can store the received package name in the internal memory and update it (S805).

When the TCP packet is generated from the application layer, the terminal 820 refers to the pre-stored package name and application / package name mapping table, and receives the TCP packet from the multi-path control proxy server 830 It is possible to check whether the package name exists (S806).

If the received package name exists, that is, it is confirmed that the multipath service for the application is available, the terminal 820 can transmit the generated TCP packet to the multipath proxy server (S807).

If it is determined in step 806 that the received package name does not exist, the terminal 820 can determine that the multi-path service is not provided for the corresponding application, and transmits the generated TCP packet to the active network , And the network may be either a mobile communication network or a Wi-Fi network - (S808).

9 to 10 are views for explaining a multi-path service control flow and a user interface screen in a terminal according to an embodiment of the present invention.

Referring to FIG. 9, the terminal may display a predetermined multi-path service setting screen 900 according to a user's selection of a predetermined menu. The multipath service setting screen 900 may include a predetermined multipath service setting button 910 for enabling (ON) / deactivating (OFF) the multipath service and a guide message 920 for the multipath service have.

If the user clicks the multi-path service setting button 910 in order to activate the multi-path service in a state in which the multi-path service setting button 910 is displayed in an OFF state (S901) (S902). ≪ / RTI >

If it is determined in step 902 that the subscriber is not subscribed to the data infinite rate plan, the terminal may output a predetermined announcement message indicating that the multi-path service (multi-path service) can not be used in the subscription plan (S903).

If it is determined in step 902 that the mobile terminal is subscribed to the data infinite rate plan, the mobile station can confirm the activation status of the LTE (mobile communication network) and the Wi-Fi (short range wireless communication network).

As a result of the state check in step 904, if only LTE or Wi-Fi is activated, the mobile terminal can enter the connector A of FIG. 10, which will be described later.

On the other hand, if it is determined in step 904 that both LTE and Wi-Fi are activated, the UE changes the state of the multi-path service setting button 910 to the ON state as shown in reference numeral 930 Can be displayed.

Referring to FIG. 10, if it is determined in step 904 that Wi-Fi is in an OFF state and LTE is in an ON state, the terminal must activate Wi-Fi to use the multi-path service The user can display a predetermined pop-up screen 1010. Here, a predetermined confirmation button for activating the inactivated Wi-Fi may be included in one side of the pop-up screen 1010. At this time, if the OK button is selected, the terminal can activate Wi-Fi and change the state of the multipath service setting button 910 to the ON state, as shown in reference numeral 1030. In addition, a predetermined cancel button for keeping the multipath service in the OFF state may be included in one side of the pop-up screen 1010. [

If the Wi-Fi is in the ON state and the LTE is in the OFF state as a result of the checking in step 904, the terminal displays a predetermined pop-up screen informing that the LTE should be activated for using the multipath service, As shown in FIG. In this case, a predetermined confirmation button for activating the inactivated LTE may be included in one side of the pop-up screen. When the confirmation button is selected, the terminal activates LTE and, as shown in reference numeral 1030, 910 can be changed to the ON state and displayed. In addition, a predetermined cancel button for keeping the multipath service in the OFF state may be included in one side of the pop-up screen 1020.

11 is a flowchart illustrating a signaling procedure for setting and canceling a multipath service according to an embodiment of the present invention.

11, the terminal 1120 can transmit a predetermined multi-path control proxy server address request message to the DNS (Domain Name Server) 1130 when the multi-path service activation (ON) menu is selected (S1102).

The DNS 1130 may transmit a predetermined multipath control proxy server address response message including connection IP address information to the multipath control proxy server 1140 to the terminal 1120 (S1103).

If the connection IP address information to the received multipath control proxy server 1140 exists in the terminal 1120, the terminal 1120 may skip steps 1102 and 1103 described above.

The terminal 1120 may transmit a multi-path service activation request message including the terminal information to the multi-path control proxy server 1140 using the connection IP address information to the multi-path control proxy server 1140 (S1104).

The multi-path control proxy server 1140 may transmit to the terminal 1120 a multi-path service activation response message including the information about whether to accept the multi-path service request and the package name corresponding to the terminal information (S1105).

If the multi-path service request is accepted, the terminal 1120 can update the received package name and activate the multi-path service (S1106). The TCP packet of the application corresponding to the package name can be transmitted to and received from the multipath control proxy server 1140 (S1106 to S1107).

If the multi-path service deactivation (OFF) menu is selected while the multi-path service is activated, the terminal 1120 transmits a multi-path service deactivation request message including the terminal information to the multi-path control proxy server 1140 (S1108 to S1109).

When the MSS 1120 receives the MSS response message from the MSS 1140, the MSS 1120 may disable the MSS (S1110 to S1111). At this time, the package name updated in step 1106 may be maintained in the internal memory of the terminal 1120.

The status query time information may be information for identifying a period in which the status of the multi-path control proxy server is inquired. For example, the state query time may be set in seconds / minutes / time units, but is not limited thereto.

The MS according to an exemplary embodiment of the present invention may transmit a predetermined multipath service status query message including MS information to the MSS according to a period corresponding to the status query time information. The multi-path control proxy server may transmit to the terminal a multipath service status query response message including multipath service availability information, an application list capable of multipath services, and / or a package name corresponding to the application list. Then, the terminal can confirm whether the multipath service can be supported on the multipath control proxy server based on the received multipath service availability state information, update the received package name in a predetermined recording area, Can be identified.

The MS according to another embodiment of the present invention may transmit the multi-path service status inquiry message to the multi-path control proxy server when a specific terminal event is detected regardless of the period corresponding to the status inquiry time information. Here, the specific terminal event for transmitting the multi-path service status inquiry message may include an access or disconnection event to the mobile communication network or the short-range wireless communication network, an activation or deactivation event of the airplane mode, a reboot event, And the terminal can determine that a specific terminal event for transmitting the multi-path service status inquiry message is generated when the IP address for the TCP communication is changed.

12 is a flowchart illustrating a method of updating an application list for a multi-path packet data service according to an embodiment of the present invention.

Referring to FIG. 12, the terminal 1320 may transmit a multi-path service activation request message including terminal information to the multi-path control proxy server 1330 according to the selected multi-path service activation menu (S 1301).

The multi-path control proxy server 1330 identifies the multi-path service target application list corresponding to the terminal information and extracts the registered package information for each application included in the applicable application list (S1302 to S1303). Here, the application-specific package information may be stored in a predefined application / package mapping table and maintained in the terminal 1320 and the multipath control proxy server 1330. Here, the package information may be a package name, and the package name may include at least one of service provider information, application manufacturer information, OS type identification information, and unique application identification information. For example, the package name may be in the form of com.adroid.aaa, but is not limited thereto and may be information for uniquely identifying a specific application capable of multipath services within the terminal 1320 and the multipath control proxy server 1330 .

The multi-path control proxy server 1330 may transmit the multi-path service activation response message including the extracted package information and the status query time information to the terminal 1320 (S1304). At this time, the terminal 1320 stores and updates the received package information in a predetermined internal recording area, and drives a predetermined state query timer based on the received state query time information (S1305).

If the state query timer expiration event is detected, the terminal 1320 can reset the state query timer after transmitting the multipath service state query request message including the terminal information to the multi-path control proxy server 1330 (S1306 - S1308). Here, the terminal information includes at least one of International Mobile Subscriber Identification (IMSI) information, Mobile Station International ISDN Number (MSISDN), International Mobile Equipment Identity (IMEI) information, terminal IP information, But is not limited to this.

The multi-path control proxy server 1330 can check whether or not the package information corresponding to the terminal information has been updated (S1309). At this time, the multi-path control proxy server 1330 may further check whether the multi-path service can be provided based on the network status, whether the multi-path control proxy server 1330 is in a failure state, or the like.

As a result of checking, when the package information is updated, the multi-path control proxy server 1330

Path service inquiry response message including information on whether or not the multi-path service can be provided and the updated package information to the terminal 1320 (S1310). The terminal 1320 can store the updated package information in a predetermined recording area (S1311). Thereafter, the terminal 1320 transmits the TCP packet generated by the application layer of the terminal 1320 to the multi-path control proxy server 1330 using the multi-path according to the updated package information, The generated TCP packet can be transmitted to the corresponding content server or the web server without passing through the control proxy server 1330. [

If it is determined in step 1309 that the package information corresponding to the terminal information is not updated, the multi-path control proxy server 1330 transmits a multi-path service status query response Message to the terminal 1320 (S1312).

If the terminal 1320 receives the multi-path service status query response message indicating that the multi-path service can not be provided, the terminal 1320 may block the multipath service from being activated internally. For example, if it is determined that the multi-path service can not be provided, the terminal 1320 may prevent the multi-path service activation request message from being transmitted to the multi-path control proxy server 1330 according to the user's predetermined menu selection, Thereby preventing the multipath service from being activated.

The multi-path control proxy server 1330 may also transmit a predetermined multi-path service status change message to the terminal 1320 when the multi-path control proxy server 1330 is changed from a state in which the provision of the multi-path service is impossible to a possible state. In this case, the terminal 1320 can unblock the blocked multipath service according to the multipath service status change message. Thereafter, the user can activate the multipath service through the selection of the predetermined multipath service menu.

13 is a flowchart illustrating a method of updating an application list for a multi-path packet data service according to another embodiment of the present invention.

13, when a specific terminal event is detected while the multipath service is activated, the terminal 1420 transmits a multi-path service status inquiry request message including terminal information to the multi-path control proxy server 1430 (S1401 to S1403). Here, the specific terminal event may include an access or disconnection event, an activation or deactivation event of the airplane mode, a reboot event, and the like to or from the mobile communication network or the local area wireless communication network. However, It can be determined that a specific terminal event for transmitting the multi-path service status inquiry message is generated.

The multi-path control proxy server 1430 can check whether or not the package information corresponding to the terminal information has been updated (S1405). At this time, the multi-path control proxy server 1430 may further check whether or not the multi-path service can be provided based on the network state information, information on whether the multi-path control proxy server 1430 is in a failure state, and whether the multi-path control proxy server 1430 is overloaded. Here, the network status information may include, but is not limited to, available bandwidth information of the mobile communication network and the short-range wireless communication network, transmission delay time information, information on a packet data transmission error rate, .

As a result of checking, when the package information is updated, the multi-path control proxy server 1430

Path service status query response message including information on whether or not the multi-path service can be provided and updated package information to the terminal 1420 (S1407). The terminal 1420 can store the updated package information in a predetermined recording area (S1409). Thereafter, the terminal 1420 transmits the TCP packet generated by the application layer of the terminal 1420 according to the updated package information to the multi-path (for example, a path via the mobile communication network and the local area wireless communication network) It is possible to transmit the generated TCP packet to the control proxy server 1430 without passing through the multipath control proxy server 1430 using a single path, for example, a path via a mobile communication network or a short- Server or a web server.

If it is determined in step 1405 that the packet information corresponding to the terminal information is not updated, the multi-path control proxy server 1430 transmits a multi-path service status query response including information on whether the multi- Message to the terminal 1420 (S1411).

If the terminal 1420 receives the multi-path service status query response message indicating that the multi-path service can not be provided, the terminal 1420 may block the multipath service from being activated internally.

In addition, the multi-path control proxy server 1430 may transmit a predetermined multi-path service status change message to the terminal 1420 when the multi-path control proxy server 1430 is changed from a state where the provision of the multi-path service is impossible to a possible state. In this case, the terminal 1420 can unblock the blocked multipath service according to the multipath service status change message. Thereafter, the user can activate the multipath service through the selection of the predetermined multipath service menu.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

610: application server
620: Multipath Service Control Proxy Server
630:
640: Internet network
650: Mobile communication network
660: Short-range wireless communication network
621: TCP layer
622: Multipath control layer
623: TCP subflow layer

Claims (25)

A method of updating an application list for a multi-path packet data service in a multi-path control proxy server interworking with a terminal,
Transmitting a multi-path service activation response message including package information for identifying a multi-path service target application to the terminal according to reception of a multi-path service activation request message including terminal information from the terminal;
Receiving a multi-path service status inquiry request message including terminal information from the terminal;
Confirming whether the package information corresponding to the terminal information has been changed; And
Transmitting the multi-path service status inquiry response message including the changed package information to the terminal when the package information is changed as a result of the checking;
And updating the application list for the multi-path packet data service. The method according to claim 1,
The multi-path service activation response message further includes status inquiry time information, and receives the multi-path service status inquiry request message from the terminal at a period corresponding to the status inquiry time information. How to update. The method according to claim 1,
Wherein the multi-path service status inquiry message is received when a specific terminal event is generated in the terminal. The method of claim 3,
Wherein the specific terminal event includes an event that the IP address of the terminal is changed. 5. The method of claim 4,
The event in which the IP address of the terminal is changed includes at least one of an event of connection or disconnection, an activation or deactivation event of the airplane mode, and a reboot event to the mobile communication network or the local area wireless communication network. Way. 6. The method of claim 5,
Wherein the mobile communication network includes at least one of an LTE (Long Term Evolution) network and an LTE-Advanced network, and the short-range wireless communication network includes a Wi-Fi network. The method according to claim 1,
Further comprising the step of determining whether the multi-path packet data service can be provided to the terminal when the multi-path service status inquiry message is received, A method for updating an application list for a multi-path packet data service, the multi-path service status inquiry message further comprising: The method according to claim 1,
And the package information includes information for identifying a multi-path service target application list corresponding to the terminal information. 9. The method of claim 8,
Wherein the package information includes a predefined package name for each application included in the application list. 10. The method of claim 9,
Wherein the package name comprises at least one of service provider information, application manufacturer information, OS type identification information, and unique application identification information. The method according to claim 1,
Receiving a TCP (Transmission Control Protocol) packet generated by an application corresponding to the package information from an application server through a first TCP session; And
Distributing the received TCP packet to the first and second TCP subflow sessions established with the terminal and transmitting
And updating the application list for the multi-path packet data service. 12. The method of claim 11,
Receiving a TCP packet generated in an application corresponding to the package information from the terminal through the first and second TCP subflow sessions; And
And merging the TCP packets received through the first and second TCP subflow sessions and transmitting the merged TCP packets to the application server through the first TCP session
And updating the application list for the multi-path packet data service. 13. The method of claim 12,
Wherein the first TCP session is a TCP session established between the application server and the multi-path control proxy server via the Internet network. 13. The method of claim 12,
Wherein the first and second TCP subflow sessions include a TCP session established between the multi-path control proxy server and the MS via the mobile communication network, and a TCP connection established between the multi-path control proxy server and the MS via the short- A method for updating an application list for a multipath packet data service. 3. The method of claim 2,
Wherein the state query time information is determined based on at least one of a load and a failure state of the multipath control proxy server, a network fault between the terminal and the multipath control proxy server, and a load state. Application list update method. The method according to claim 1,
The terminal information includes at least one of International Mobile Subscriber Identification (IMSI) information, Mobile Station International ISDN Number (MSISDN) information, terminal IP information, and terminal model name information. How to update the list. A method of updating an application list for a multi-path packet data service in a terminal interworking with a multi-path control proxy server,
Transmitting a multi-path service activation request message to the multi-path control proxy server according to a user menu selection;
Receiving from the multi-path control proxy server a multi-path service activation response message including first package information and status query time information for identifying the multi-path service target application; And
And transmitting the multi-path service status inquiry request message including the terminal information to the multi-path control proxy server periodically based on the status inquiry time information
And updating the application list for the multi-path packet data service. 18. The method of claim 17,
And transmitting the multi-path service status inquiry message to the multi-path control proxy server when a specific terminal event is detected. 19. The method of claim 18,
Wherein the specific terminal event is an event that is detected when an IP address of the terminal is changed. 20. The method of claim 19,
The event in which the IP address of the terminal is changed includes at least one of an event of connection or disconnection, an activation or deactivation event of the airplane mode, and a reboot event to the mobile communication network or the local area wireless communication network. Way. 19. The method of claim 18,
Receiving a multipath service status query response message including second package information; And
Updating the first package information with the two-package information
And updating the application list for the multi-path packet data service. 22. The method of claim 21,
The multi-path service status inquiry response message may further include information on whether the multi-path service can be provided. If it is determined that the multi-path service can not be provided, the multi- A method for updating an application list for a multipath packet data service. A computer-readable recording medium having recorded thereon a program for executing the method according to any one of claims 1 to 22. 1. A multi-path control proxy server for providing a multi-path packet data service in cooperation with a terminal,
Means for transmitting a multi-path service activation response message including package information for identifying a multi-path service target application to the terminal according to reception of a multi-path service activation request message including terminal information from the terminal;
Means for receiving a multi-path service status query request message including terminal information from the terminal;
Means for confirming whether the package information corresponding to the terminal information has been changed; And
And transmitting the multi-path service status inquiry response message including the changed package information to the terminal when the package information is changed as a result of the checking
And a multi-path control proxy server. A terminal for providing a multi-path packet data service in cooperation with a multi-path control proxy server,
Means for transmitting a multi-path service activation request message to the multi-path control proxy server according to a user menu selection;
Means for receiving a multipath service activation response message including first package information and state query time information for identifying the multipath service target application from the multipath control proxy server; And
Means for periodically transmitting to the multi-path control proxy server a multi-path service status inquiry request message including terminal information based on the status inquiry time information;
.

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