KR20140026569A - Method of communication under network condition converging cellular network and wlan - Google Patents

Abstract

The present invention relates to a communication method for an access control apparatus under a network condition integrating a cellular network and a WLAN, the method comprising the steps of: receiving an uplink data package from a user equipment; Retrieving a destination address of the uplink data package from the received uplink data package; Determining an attribute of the destination address, and if the destination address has an attribute of the fixed network segment, then routing the uplink data package to the fixed access network through a network address translation (NAT) function; If the destination address has attributes of the mobile core network segment, then routing the uplink data package to the mobile core network through a network address translation (NAT) function. Using the method of the present invention, WLAN and mobile core networks are simply integrated together, reducing the load on cellular access networks and mobile core networks. In addition, the proposed method will not affect other network parts and thus has the advantage of good compatibility.

Description

METHOD OF COMMUNICATION UNDER NETWORK CONDITION CONVERGING CELLULAR NETWORK AND WLAN

TECHNICAL FIELD The present invention relates to a mobile communication network, and more particularly, to a communication method under network conditions that converge a cellular network and a WLAN.

With the development of mobile communication networks, more and more smart terminals access mobile data traffic through the mobile communication network, which results in an increase in the load of the mobile access network and the core network. The capacity of the mobile access network and core network cannot keep up with explosive user data traffic, which results in congestion or collision of the network, especially in areas where many subscribers frequently access data traffic. Therefore, operators are looking for load reduction solutions that can effectively reduce the load on mobile access networks and mobile core networks.

Meanwhile, Wi-Fi technology has been rapidly developed. Due to the fact that Wi-Fi has the advantages of wide bandwidth and low cost, more and more subscribers use mobile local area network (WLAN) resources to access mobile data traffic in accordance with Wi-Fi technology. Therefore, it is desirable to reduce the load on a mobile communication network via a WLAN using Wi-Fi technology.

The 3rd Generation Partnership Project (3GPP) standard specifies architectures for interworking Wi-Fi and 3GPP networks, called interworking WLANs (I-WLANs), as shown in FIG. 1. In this architecture, the following access schemes are included:

a) WLAN access: provides subscribers with access to WLAN and locally connected IP networks to be authenticated and authorized through the 3GPP system

b) WLAN 3GPP access that allows WLAN user equipments (UEs) to establish a connection with external IP networks, such as 3G operator networks. Subscribers can then access 3G packet services (PS) via the WLAN. Here, the packet data network (PDN) to which the UE is connected is selected based on the type of 3G PS-based service requested by the UE. The requested 3G PS-based service is identified by the UE through a WLAN-Access Point Name (W-APN).

While the UE is accessing internet services (direct IP access) and 3GPP services (3GPP IP access) at the same time, it needs to get two IP addresses from WLAN network and PDN, for 2 reasons This is because the kind of service is provided by two networks with different mechanisms. The IP address obtained from the WLAN network is used to connect with the local transport network so that data packages sent from the UE can be routed to the Internet. The IP address assigned by the PDN is used to establish an end-to-end tunnel between the UE and the PDN so that the UE can access 3GPP services. The UE is required to have the ability to establish IPSec tunnels as well as obtain two or more IP addresses in this solution. This creates additional demands on the UE and makes it poorly compatible with existing UEs in the network.

It is an object of the present invention to provide a method in an access control apparatus of a wireless local area network (WLAN) for routing a data package according to a data package address. It is advantageous in that the demand on the UE can be simplified accordingly and a reduction in the load of the mobile core network and the cellular access network can be achieved.

According to a first aspect of the invention, a communication method for an access control apparatus under network conditions incorporating a cellular network and a WLAN is proposed. The method includes the following steps: receiving an uplink data package from user equipment; Retrieving a destination address of the uplink data package from the received uplink data package; Determine the attribution of the destination address, and if the destination address has the properties of a fixed network segment, then route uplink data packages to the fixed access network through the Network Address Translation (NAT) feature. Making; If the destination address has attributes of the mobile core network segment, then routing the uplink data package to the mobile core network through a network address translation (NAT) function.

In addition, the method includes the access control device performing authentication, authorization and accounting (AAA) of the user equipment as an agent.

According to a second aspect of the invention, a method of downlink data communication for an access control apparatus under network conditions incorporating a cellular network and a WLAN is proposed. The method includes the following steps: receiving a downlink data package; Performing a network address translation (NAT) function and forwarding the downlink data package to user equipment corresponding to the downlink data package.

Therefore, using the above technical solution, the WLAN and the mobile core network can be simply integrated together, and the load on the cellular access network and the mobile core network is reduced. Moreover, the technical solution simplifies the requirements for the UE. The UE only needs to maintain one IP address, so it is not necessary for the UE to distinguish traffic types and to select or establish a complex transport tunnel. On the other hand, the method will not affect other network devices, thus improving compatibility with existing UEs and network devices.

According to a third aspect of the invention, a method of uplink data communication for user equipment under network conditions incorporating a cellular network and a WLAN is proposed. The method includes the following steps: determining an access point name (APN) corresponding to desired data traffic; If the desired data traffic corresponds to a first type of access point name (APN), encapsulating the data package using the first address as a source address; If it is determined that the desired data traffic corresponds to a second type of access point name (APN), encapsulating the data package using the second address as the source address.

According to a fourth aspect of the present invention, a communication method for an access control apparatus under network conditions incorporating a cellular network and a WLAN is proposed. The method includes the following steps: receiving an uplink data package from user equipment; Retrieving the source address of the uplink data package from the received uplink data package; Determine if the source address is the first address assigned to the user equipment by the mobile core network or the second address assigned to the user equipment by the fixed network, and if the source address is the second address, the uplink data package is Forwarding; If the source address is the first address, then adding a head whose source address is the second address and the destination address is the mobile core network gateway address to the uplink data package and forwarding the uplink data package to the mobile core network.

According to a fifth aspect of the invention, a method of downlink data communication for an access control apparatus under network conditions incorporating a cellular network and a WLAN is correspondingly proposed, wherein the method comprises the following steps: Downlink data package Receiving; If the source address of the downlink data package has an attribute of a mobile core network segment or a fixed network segment, and if the source address has an attribute of a fixed network segment, then it is downloaded directly to the user equipment corresponding to the downlink data package. Forwarding link data packages; If the source address has attributes of the mobile core network segment, then decapsulate the downlink data package, retrieve the original data package with the destination address, which is the address assigned to the user equipment by the mobile core network, And then forwarding the raw data package to the user equipment.

As a result, using the above technical solution, even if one UE maintains two IP addresses, the UE can be simplified because the UE does not need to establish a tunnel or support a complex tunnel protocol. . In addition, the technical solution brings an anchor to the WLAN, thereby ensuring the mobility of the service. When the UE enters or leaves the WLAN, the continuity of the conversation can be maintained without establishing a conversation again.

According to a sixth aspect of the present invention, a DSMIP-based communication method for an access control apparatus under network conditions incorporating a cellular network and a WLAN is proposed. The method includes the following steps: receiving an uplink data package encapsulated according to the DSMIP protocol from a user equipment; Detecting a destination address of the original data package in the uplink data package encapsulated according to the DSMIP protocol, and determining its attribute; If the destination address has attributes of the fixed network segment, then discarding the head of the DSMIP protocol encapsulation and routing the original data package directly to the fixed access network; If the destination address has attributes of the mobile core network segment, then routing the tunnel encapsulated uplink data package to the mobile core network.

As a result, the technical solution can reduce the load on the mobile core network and the cellular access network in the DSMIP-based network.

According to the solutions of the present invention, in the access control apparatus of the WLAN, it may be determined to route the data package via different paths according to the destination address or the source address of the data package. WLAN and mobile core networks simply integrate together and reduce the load on cellular access networks and mobile core networks. In addition, the present invention also includes the advantage that it is easy to perform uniform charging. This can help operators manage the usefulness of the WLAN by initially performing authentication that they can manage and control.

1 illustrates a topology of an I-WLAN based communication network.
2 illustrates a topology of a communication network according to an embodiment of the present invention.
3 shows a flowchart of an uplink communication method in the embodiment of FIG. 2.
4 shows a flowchart of a downlink data communication method in the embodiment of FIG.
5 shows a topology of a communication network according to another embodiment of the present invention.
6 shows a flowchart of an uplink communication method in the embodiment of FIG. 5.
7 illustrates data encapsulation of a communication method in the embodiment of FIG. 5.
8 shows a flowchart of a downlink data communication method in the embodiment of FIG.
9 illustrates a topology of a communication network according to another embodiment of the present invention.
FIG. 10 shows a flowchart of a downlink data communication method in the embodiment of FIG. 9.
The same or similar reference numerals in the drawings indicate the same or similar means.

2 illustrates a topology of a communication network under network conditions incorporating a cellular network and a WLAN in accordance with an embodiment of the present invention. As shown in FIG. 2, under network conditions incorporating a cellular network and a WLAN, a universal terrestrial radio access (UTRAN) 210, a WLAN access network 220, a mobile core network 230, a UE 250, and a fixed network (fixed network) 260 is included.

In FIG. 2, Node Bs 211, 212 are shown to UTRAN 210, Wi-Fi access points 221, 222 are shown to WLAN access network 220, and a Serving Gateway (S-GW). ) / Serving GPRS Support Node (SGSN) / Mobile Management Entity (MME) 231, Home Location Register (HLR) / Authentication, Authorization and Accounting (AAA) Register 232, Gateway Gateway GPRS Service Node (GGSN) / PDN Gateway (PGW) / Packet Data Gateway (PDG) 233 and Home Agent (HA) 234 are connected to mobile core network 230 Shown. Those skilled in the art will appreciate that only the parts necessary for the understanding of the present invention are shown here, and the components included in the mobile communication network system are not limited to those shown here.

Typically, UE 250 is via Short Message Service (SMS) via UTRAN 210, via HA 234 as well as S-GW / SGSN / MME 231 and GGSN / PGW / PDG 233. Or 3GPP services such as Voice over IP (VoIP) and the like.

In addition, the functional entity of the Wireless Access Broker (WAB) 240 integrates the network of WLAN and operators together, extends the coverage of the network and reduces the load on the mobile access network and the mobile core network. It is introduced in this embodiment to carry out. In the following, a wireless access broker (WAB) is also called an access control device.

A communication method for an access control apparatus under network conditions incorporating the cellular network and WLAN shown in FIG. 2 will be described in conjunction with FIG. 3. In step S21, the Package Data Gateway (PDG) 233 and the Dynamic Host Configuration Protocol (DHCP) (not shown in FIG. 2) of the 3G core network respond to the request of the WAB 240. Assign an IP address to it. In step S22, the WAB 240 obtains two IP addresses, respectively, from the PDG 233 and the DHCP of the mobile core network. Here, as shown in FIG. 2, the address assigned to WAB 240 by the mobile core network is labeled Addr. 1, and the address assigned to WAB by the fixed network is labeled Addr. 2.

As shown in FIG. 2, in the present embodiment, if the UE 250 is within the coverage of the Wi-Fi access point, the UE 250 connects to the WAB 240 via the Wi-Fi access point in step S11. do. After a WLAN connection is established between the UE 250 and the WAB 240, the UE 250 initiates EAP-AKA based authentication. The WAB 240 performs an authentication function in step S23 to enable authentication between the UE and the AAA / HLR server. In step S24, the WAB 240 responds to the request of the UE 250 and assigns a local IP address to the UE 250. During the service access procedure, if the UE 250 sends the 3GPP service request in step S121, after receiving the uplink data package from the UE, the WAB 240 receives the destination of the uplink data package from the received uplink data package. Search for the address, and determine the attribute of the destination address in step S25. If the destination address has the attributes of the mobile core network segment, then WAB 240 performs a network address translation (NAT) function, that is, the local IP address of UE 250 is WAB 240 from the 3G core network. Translated into Addr.1 obtained by In step S26, the data package after the NAT function is routed to the 3G core network through the tunnel between the WAB 240 and the PDG 233. If the UE 250 sends the Internet service request in step S122, after receiving the uplink data package from the UE, the WAB 240 retrieves the destination address of the uplink data package from the received uplink data package, In step S27, the properties of the destination address are determined. If the destination address has the attributes of the fixed network segment, then WAB 240 performs NAT function, that is, the Local IP address of UE 250 is obtained from Addr. 2 by WAB 240 from the fixed network. Is translated. In step S28, the data package after the NAT function is routed to the fixed network.

Those skilled in the art will appreciate that steps S23 and S24 are optional for the implementation of the present invention.

Correspondingly, FIG. 4 illustrates a method of downlink data communication under network conditions incorporating the cellular network and WLAN shown in FIG. 2. In this embodiment, in step S41, the WAB 240 receives the downlink data package from the mobile core network or the fixed network. NAT function is executed in step S42. In step S43, the downlink data package is forwarded to the UE 250 corresponding to the downlink data package. Here, when the UE switches from WLAN to mobile cellular network, the WAB can act as an anchor in the WLAN and also forward the downlink data package of the UE by establishing a tunnel to the mobility anchor of the mobile core network. do. Therefore, the anchor is brought to the WLAN, which ensures the mobility of the service, that is, when the UE enters or leaves the WLAN, the continuity of the conversation can be maintained without establishing the conversation again.

5 shows a topology of a communication network under network conditions incorporating a cellular network and a WLAN in accordance with another embodiment of the present invention. As shown in FIG. 5, under network conditions incorporating a cellular network and a WLAN, a UTRAN 510, a WLAN access network 520, a mobile core network 530, a UE 550 and a fixed network 560 are included. do.

In FIG. 5, Node Bs 511, 512 are shown to UTRAN 510, Wi-Fi access points 521, 522 are shown to WLAN access network 520, and S-GW / SGSN / MME 531. ), HLR / AAA 532, GGSN / PGW / PDG 533 and HA 534 are shown in mobile core network 530. Those skilled in the art will appreciate that only those parts necessary for an understanding of the present invention are shown herein and that the components included in the mobile communication network system are not limited to those shown here.

Typically, UE 550 via UTRAN 510, via HA 534 as well as S-GW / SGSN / MME 531 and GGSN / PGW / PDG 533, such as SMS or VoIP, and the like. Access to 3GPP services.

In addition, the functional entity of the WAB 540 can be used to perform the method according to the invention in order to integrate the WLAN and operators' networks together, to extend the coverage of the network and to reduce the load on the mobile access network and the mobile core network. It is also introduced in the examples. 2 differs from the embodiment of FIG. 2 in this embodiment that the UE 550 has two IP addresses, a first address assigned to the UE by the mobile core network and a second address assigned to the UE by the fixed IP network. Will be. And correspondingly, it is no longer necessary for the WAB to select a path for routing the uplink data package according to the destination address of the uplink data package. Instead, the WAB selects a route based on the source address of the uplink data package. In the following, WAB is also called access control device.

FIG. 6 shows a flowchart of a communication method according to an embodiment of the present invention under the network conditions shown in FIG. 5. A communication method for an access control apparatus and a UE under network conditions incorporating a cellular network and a WLAN according to an embodiment of the present invention is described with reference to FIG. 6. First, in steps S31 and S32, the PDG 533 and the fixed network of the 3G core network respond to the request of the UE 550 and assign it an IP address respectively. Here, as shown in FIG. 5, the address assigned to the UE 550 by the mobile core network is labeled Addr.1 and the address assigned to the UE 550 by the fixed network is labeled Addr.2. The UE 550 determines an access point name (APN) corresponding to desired data traffic in step S51. If the APN of the desired data traffic corresponds to the mobile core network, the UE 550 encapsulates the data package using Addr. 1 as the source address, and transmits the data package to the WAB 540 in step S52. If the UE 550 determines that the APN of the desired data traffic corresponds to the fixed network in step S55, the data package is encapsulated using Addr. 2 as the source address as shown in FIG. 7. The UE 550 transmits the data package to the WAB 540 in step S56.

After the WAB 540 receives the uplink data package from the UE, it retrieves the source address of the uplink data package from the received uplink data package and determines whether the source address is Addr.1 or Addr.2. If the source address is determined as Addr. 1 in step S53, as shown in Fig. 7, a head whose source address is the second address and the destination address is the mobile core network gateway address will be added to the uplink data package. The uplink data package is then forwarded to the mobile core network in step S54. The head is used to establish a tunnel between the WAB and the mobile core network. If the source address is determined as Addr.2 in step S57, the uplink data package will be forwarded directly via the fixed network in step S58.

Correspondingly, FIG. 8 shows a method of downlink data communication under network conditions incorporating the cellular network and WLAN shown in FIG. 5. In the above embodiments of the present invention, the WAB performs the following steps for the downlink data packages: in step S81, receiving the downlink data package from the fixed network or the mobile core network; In step S82, it is determined whether the source address of the downlink data package has an attribute of a mobile core network segment or a fixed network segment, and if the source address has an attribute of a fixed network, then in step S83 corresponding to the downlink data package Forward the downlink data package directly to the UE; If it is determined in step S84 that the source address has attributes of the mobile core network segment, then in step S85, the encapsulation of the downlink data package is performed, the original data package having the destination address of Addr.1 is retrieved, and in step S86. Forward the original data package to the UE. Therefore, the anchor is brought to the WLAN, which ensures the mobility of the service, that is, when the UE enters or leaves the WLAN, the continuity of the conversation can be maintained without establishing the conversation again.

In addition, 3GPP Rel 8 provides a Dual Stack Mobile IP (DSSMIP) mechanism that supports mobility between the cellular network and the WLAN. However, all data traffic (including 3GPP service and Internet service) needs to be aggregated to the mobile core network (HA router) while implementing this mechanism. In accordance with the teachings of the present invention, FIG. 9 illustrates a topology of a communication network under network conditions incorporating a cellular network in accordance with another embodiment of the present invention. As shown in FIG. 9, under network conditions incorporating cellular networks, UTRAN 910, WLAN access network 920, mobile core network 930, UE 950 and fixed network 960 are included.

In FIG. 9, Node B 911, 912 is shown to UTRAN 910, Wi-Fi access points 921, 922 are shown to WLAN access network 920, and S-GW / SGSN / MME 931. ), HLR / AAA 932, GGSN / PGW / PDG 933, and HA 934 are shown in mobile core network 930. Those skilled in the art will appreciate that only parts necessary for the understanding of the present invention are shown herein and that the components included in the mobile communication network system are not limited to those shown herein.

Typically, UE 950 via UTRAN 910, via HA 934 as well as S-GW / SGSN / MME 931 and GGSN / PGW / PDG 933, such as SMS or VoIP, etc. Access to 3GPP services.

In addition, the functional entity of the WAB 940 can be used to perform the method according to the invention in order to integrate the WLAN and operators' networks together, to extend the coverage of the network and to reduce the load on the mobile access network and the mobile core network. It is also introduced in the examples. In this embodiment, the UE 950 has a Home Address (HoA) of 166.111.4.222 assigned by the mobile core network. When the UE switches to the WLAN, the WLAN assigns it a Care of Address (CoA) of 172.24.149.166. The destination address that the UE attempted to access is 162.105.203.16. UE 950 encapsulates data packages according to the DSMIP protocol, establishes a tunnel for HA, and transmits data packages.

Here, the WAB 940 according to the present invention performs the following steps: in step S91, receive an uplink data package encapsulated according to the DSMIP protocol from the UE 950; Detect a destination address of the original data package in the uplink data package encapsulated according to the DSMIP protocol in step S92, and determine its attribute; If the destination address has attributes of the mobile core network segment, then in step S93, route the tunnel encapsulated uplink data package to the mobile core network; If the destination address has the attributes of the fixed network segment, then in step S94 discard the head of the DSMIP protocol encapsulation, and in step S95 route the original data package directly to the fixed access network.

In the embodiment shown in FIG. 9, the WAB 940 can retrieve the destination address 166.111.4.222 of the original data package by unencapsulating the received data package. The destination address is determined to have the attributes of the fixed network segment. The WAB 940 discards the head of the DSMIP protocol encapsulation and routes the original data package to the destination address in the fixed access network. Therefore, the mobile core network reduces the load while ensuring the mobility of services.

Those skilled in the art will readily appreciate that the present invention is not limited to the details of these exemplary embodiments. Other embodiments may be used to implement the invention without departing from the spirit or basic features thereof. Therefore, the embodiments are to be considered illustrative and non-limiting. In addition, the term “comprise” does not exclude the presence of other element (s) or step (s); Indefinite articles (a / an) do not exclude "multiple" cases. The terms "first" and "second" are used merely to give a name rather than to indicate a particular order.

Claims (10)

A communication method for an access control apparatus under a network condition that converges a cellular network and a WLAN, the method comprising:
a. Receiving an uplink data package from the user equipment;
b. Retrieving a destination address of the uplink data package from the received uplink data package;
c. Determine the attribute of the destination address, and if the destination address has an attribute of a fixed network segment, route the uplink data package to the fixed access network through a network address translation (NAT) function and; If the destination address has attributes of a mobile core network segment, routing the uplink data package to the mobile core network via a NAT function
/ RTI > The method of claim 1, wherein the access control device comprises performing authentication, authorization and accounting (AAA) of the user equipment as an agent. The method of claim 1, wherein the access control device comprises assigning a local area network (LAN) address to the user equipment. A downlink data communication method for an access control apparatus under network conditions integrating a cellular network and a WLAN, the method comprising:
d. Receiving a downlink data package;
e. Performing a network address translation (NAT) function and forwarding the downlink data package to user equipment corresponding to the downlink data package
/ RTI > An uplink data communication method for user equipment under network conditions integrating cellular network and WLAN, the method comprising:
A. determining an access point name (APN) corresponding to desired data traffic;
B. If the desired data traffic corresponds to a first type of APN, encapsulate the data package using the first address as a source address; If it is determined that the desired data traffic corresponds to a second type of APN, encapsulating the data package using the second address as the source address;
/ RTI > 6. The method of claim 5, wherein the APN of the first type of desired data traffic corresponds to a mobile core network, the APN of the second type of desired data traffic corresponds to a fixed network,
The first address is an address assigned to the user equipment by the mobile core network; And the second address is an address assigned to the user equipment by the fixed network. A communication method for an access control apparatus under network conditions integrating a cellular network and a WLAN, the method comprising:
i. Receiving an uplink data package from the user equipment;
ii. Retrieving a source address of the uplink data package from the received uplink data package;
iii. Determine if the source address is a first address assigned to the user equipment by a mobile core network or a second address assigned to the user equipment by a fixed network; and if the source address is the second address, the fixed Forwarding the uplink data package over a network; If the source address is the first address, add a head having a source address to the second address and a destination address to the mobile core network gateway address to the uplink data package and then package the uplink data package to the mobile core network. Steps to Forward
/ RTI > A downlink data communication method for an access control apparatus under network conditions integrating a cellular network and a WLAN, the method comprising:
iv. Receiving a downlink data package;
v. Determine if the source address of the downlink data package has attributes of a mobile core network segment or a fixed network segment, and if the source address has attributes of the fixed network segment, then send the user equipment corresponding to the downlink data package Forward the downlink data package directly; If the source address has attributes of the mobile core network segment, decapsulating the downlink data package, and the original data package with a destination address that is an address assigned to the user equipment by the mobile core network. Retrieving and forwarding the raw data package to the user equipment
/ RTI > The device of claim 4 or 8, wherein when the user equipment is switched from a WLAN to a mobile cellular network, the access control device establishes a tunnel to the mobile core network mobility anchor. Communication method of forwarding downlink data package of equipment. A DSMIP-based communication method for an access control device under a network condition integrating a cellular network and a WLAN,
a. Receiving an uplink data package encapsulated according to the DSMIP protocol from the user equipment;
b. Detecting a destination address of the original data package in the uplink data package encapsulated according to the DSMIP protocol and determining its attribute;
c. If the destination address has attributes of a fixed network segment, discard the head of DSMIP protocol encapsulation and route the original data package directly to the fixed access network; If the destination address has attributes of a mobile core network segment, routing a tunnel encapsulated uplink data package to the mobile core network
/ RTI >

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