JP2011166432A - Packet transfer device, communication system, and packet transfer method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a packet transfer device that transfers signaling messages without termination processing. <P>SOLUTION: The packet transfer device for transferring the signaling messages received from a communication device to the other communication device is configured: to conduct transmission and reception between the communication devices on the basis of a lower-layer protocol of a signaling protocol; and to acquire identification information of the connection as connection information at the time of setting the connection on the basis of the lower-layer protocol. The packet transfer device also includes an Ihu side processing part 21 and an Iu side processing part 22 for transferring the signaling messages on the basis of the identification information and the connection information on the connection of the lower-layer protocol extracted from the received signaling messages, and a storing part 29 for holding the connection information. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a packet transfer apparatus, a communication system, and a packet transfer method for transferring a signaling message.

  As a conventional signaling message transfer method, for example, in the technique described in Patent Document 1 below, an IWF (InterWorking Function) device that connects devices using different physical lines mainly performs signaling control. And IWF-u that mainly transfers user data. The IWF-c recognizes call information by terminating one end of a SCCP (Signaling Connection Control Part). When an RNC (Radio Network Controller) transmits an “Initial UE (User Equipment) Message” to an MSC (Mobile Switching Center), the SCCP between the RNC and the IWF-C and between the IWF-c and the MSC. A connection is set up, and a connection correspondence table corresponding to the same call is created. Then, the IWF device selects an appropriate transmission / reception unit from among a plurality of control signal transmission / reception units in the RNC by performing transfer using this correspondence table.

  Further, as a device for connecting devices using different physical lines, 3GPP (3rd Generation Partnership Project) TS. There is HNB-GW (3G Home Node B Gateway) defined in 25.467 (see Non-Patent Document 1 below).

International Publication No. 2004/077772

3GPP, “3GPP TS 25.467 V8.1.0”, 2009-03

  However, according to the technique described in Patent Document 1, since the SCCP connections are associated with each other, there is a problem that it is not possible to cope with the case where the protocol is different between the RNC side and the MSC side. In the technique described in Patent Document 1, the signaling message is once terminated and transferred. For this reason, there is a problem that a device for transferring a signaling message needs to have a function of terminating the signaling message.

  Moreover, in the said nonpatent literature 1, although there exists description about the signaling protocol on Iu (interface with CN (Core Network)) and its process in HNB-GW, Iuh (HNB (Home Node B) and There is no description regarding packet transfer of signaling messages between the interface between Iu and Iu. Therefore, when transferring an HNB-GW signaling message, there is a problem that it is necessary to have a function of terminating the signaling message.

  The present invention has been made in view of the above, and an object of the present invention is to obtain a packet transfer apparatus, a communication system, and a packet transfer method that can transfer a signaling message without performing termination processing. It is another object of the present invention to provide a packet transfer apparatus, a communication system, and a packet transfer method that can transfer a signaling message when a transfer source and a transfer destination use different protocols.

  In order to solve the above-described problem and achieve the object, the present invention connects two or more communication devices, and transmits a signaling message generated based on a signaling protocol received from the communication device to other communication devices. A packet transfer device that transfers to a device, performs transmission / reception processing with the communication device based on a lower layer protocol of the signaling protocol, and identifies the connection when setting a connection based on the lower layer protocol A protocol processing means for acquiring information as connection information; and a storage means for holding the connection information. The protocol processing means stores the connection information in the storage means and extracts it from the received signaling message. The connection identification information of the lower layer protocol Based on said connection information and transfers the signaling messages, characterized in that.

  According to the present invention, the packet transfer apparatus includes: a first protocol processing unit that performs communication protocol processing on the first interface side; and a second protocol processing unit that performs communication protocol processing on the second interface side. And the first protocol processing means and the second protocol processing means hold the correspondence between the connection identification information on the first interface side indicating the same connection and the connection identification information on the second interface side. Based on this, since the signaling message is transferred, the signaling message can be transferred without performing termination processing. In addition, the signaling message can be transferred when the transfer source and the transfer destination use different protocols.

FIG. 1 is a diagram illustrating a configuration example of a communication system according to the first embodiment. FIG. 2 is a diagram illustrating an example of a protocol stack of each device constituting the communication system according to the first embodiment. FIG. 3 is a diagram illustrating a functional configuration example of the HNB-GW according to the first embodiment. FIG. 4 is a diagram illustrating a mapping image of each protocol connection. FIG. 5 is a chart diagram illustrating an example of a procedure for creating a mapping table according to the first embodiment. FIG. 6 is a diagram illustrating an example of correspondence between logical identification information and identification information of each connection.

  Embodiments of a packet transfer apparatus, a communication system, and a packet transfer method according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration example of a first embodiment of a communication system according to the present invention. As shown in FIG. 1, the communication system according to the present embodiment includes a mobile terminal UE1, a femtocell base station (HNB) 2, an HNB-GW 3, a CN 4, a security gateway (security device) 5, HMS (HNB Management System: femtocell base station management system) 6. In the present embodiment, the HNB-GW 3 will be described as an example of the packet transfer apparatus according to the present invention.

  The HNB 2 is connected to one or more UEs 1 via the Uu interface 11 (in FIG. 1, only one UE 1 is shown for simplicity). FIG. 1 is an example of a system configuration diagram showing a mobile communication system of the present invention. The HHNB-GW 3 is connected to one or more HNBs 2 via the Iuh interface 12 (in FIG. 1, only one HNB 2 is shown for simplification).

  Since the public network may be included between HHNB-GW3 and HNB2, Security Gateway 5 for performing processing for securing security (security processing) is provided in the configuration example of FIG. If security processing is not required, such as when the public network is not included between HHNB-GW3 and HNB2, Security Gateway 5 may not be provided.

  The HHNB-GW 3 is connected to the CN 4 via the Iu interface 13. The HMS 6 is connected to the HNB-GW 3 via the TR-069 interface 14 and performs configuration management of the HNB 2 and the HNB-GW 3.

  FIG. 2 is a diagram illustrating an example of a protocol stack of each device constituting the communication system of the present embodiment. Here, it is assumed that the network between CN4 and HNB2 is configured by an IP (Internet Protocol) network, Ethernet (registered trademark) exists in the lowest layer, and IP protocol exists in layer 3. Further, in Layer 4, there is a SCTP (Stream Control Transmission Protocol) protocol for reliable transfer of IP packets.

  Between HNB3 and HNB2, as a security function, for example, IPsec (Security Architecture for Internet Protocol) defined in RFC (Request for Comments) 4306 exists.

  Between the CN4 and the HNB-GW3, there are SCCP and M3UA (Message Transfer Part 3 User Adaptation) for transferring the common line signal through the IP network. Similarly, there is a RUA (RANAP User Adaptation) for transferring a common line signal between the HNB-GW 3 and the HNB 2.

  In addition, in HNB2 and CN4, there is a RANAP (Radio Access Network Application Part) protocol for setting radio access bearers and managing radio bearer resources. Further, RUA and SCCP have a function of transferring a RANAP protocol message (RANAP message). In HNB-GW2, RUA and SCCP transfer a RANAP message on RUA and SCCP. The RANAP protocol has a function of transferring a NAS (Non Access Stratum) message that is a message between the CN 4 and the UE.

  Between UE1 and HNB, there is Radio-PHY (Radio Physical Layer) in the lowest layer, and RLC (Radio Link Control) / MAC (Medium Access Control) is above it. Moreover, there is RRC (Radio Resource Control), and there is NAS. The NAS message is transferred via the RRC protocol in the Uu interface. In HNB2, the NAS message on the RRC protocol and the NAS message on the RRC protocol are converted and transferred. In 3GPP, transfer of NAS messages on RRC messages and RANAP messages is the same as the conventional method defined in 3GPP.

  FIG. 3 is a diagram illustrating a functional configuration example of the HNB-GW 3 according to the present embodiment. As shown in FIG. 3, the HNB-GW 3 of the present embodiment includes an Iuh side processing unit (first protocol processing unit) 21, an Iu side processing unit (second protocol processing unit) 22, and a storage unit 29. Composed. The Iuh side processing unit 21 and the Iu side processing unit 22 are protocol processing units that perform protocol processing lower than RANAP, which is the protocol of the signaling message to be transferred here.

  The Iuh-side processing unit 21 includes an RUA protocol processing unit 23 that performs RUA protocol processing, an SCTP protocol processing unit 24 that performs SCTP protocol processing, and a lower layer processing unit 25 that performs processing of IP and lower layers. . The Iu-side processing unit 22 includes an SCCP protocol processing unit 26 that performs SCCP protocol processing, an SCTP protocol processing unit 27 that performs SCTP protocol processing, a lower layer processing unit 28 that performs processing of IP and lower layers, Is provided.

  Next, the operation of the present embodiment will be described. First, the connection mapping operation (connection association operation) of the present embodiment will be described by taking as an example the case where the RANAP message transmitted from the CN 4 is transferred.

  FIG. 4 is a diagram illustrating a mapping image of each protocol connection. In the example of FIG. 4, when the first RANAP message (Initial UE Message) is transmitted from the UE 1 to the CN 4, the inter-layer correspondence 34 of the Iu-side SCCP connection 32 and the Iu-side SCTP association 31, the Iuh-side RUA connection 36, and the Iuh The mapping table (connection information) includes the inter-layer correspondence 37 of the side SCTP association 35 and the inter-peer correspondence 38 between the Iuh RUA connection 36 and the Iu SCCP connection 32, which is a correspondence between the Iu side and the Iuh side. Is created as Assume that these mapping tables are held in the storage unit 29. A method for creating the mapping table will be described later. In this embodiment, since the RANAP termination process is not performed and the RANAP message is transferred on the SCCP (and on the RUA), the RANAP connection 33 corresponds to the SCCP connection in which the RANAP is encapsulated. .

  FIG. 4 shows an example in which the HNB-GW 3 is connected to N + 1 HNBs HNB2-0 to HNB2-N. In the created mapping table, as shown in FIG. 4, the SCTP association # 0 of the Iu-side SCCP association 31 between the HNB-GW3 and the CN4 is the SCCP connection # 0 to the SCCP connection #M (Iu-side SCCP connection 32). Assume that M is associated with an integer of 0 or more. The SCTP association # 0 of the Iu-side SCTP association is assumed to be associated with SCTP association # 0 to SCTP association #N (N is an integer of 0 or more) of the Iuh-side SCTP association 35.

  Also, the RUA connection # 0, RUA connection # 1,..., RUA connection #M of the Iuh side RUA connection 36 correspond to the SCCP connection # 0, SCCP connection # 1,... SCCP connection #M of the Iu side SCCP connection 32, respectively. Suppose that it is attached. Also, the correspondence between the Iuh side RUA connection 36 and the Iuh side SCTP association 35 is shown in FIG. 4 for the sake of brevity, and the portion of HNB2-N is shown. Assume that the connection 36 corresponds to the RUA connection # M-1 and the RUA connection #M.

  As identification information for identifying SCCP connection # 0 to SCCP connection #M, it is assumed that values of Destination Local Reference and Source Local Reference for each connection identification are held. Further, as identification information for identifying the SCTP association (each connection of the Iu side SCTP association 31 and the Iuh side SCTP association 35), IP DA (Destination Address), IP SA (Source Address), Destination Port, and Source Port for each association. Assume that the value of DL Verification Tag is held. Further, it is assumed that RUA Context ID (IDentifier) for each connection is held as identification information for identifying RUA connection # 0 to RUA connection #M. Note that these pieces of identification information are not necessarily required as long as a connection can be specified.

  Here, the mapping table is held as a table that associates the above-described identification information. For example, the mapping table of the inter-layer correspondence 34 between the Iu-side SCCP connection 32 and the Iu-side SCTP association 31 corresponds to Destination Local Reference and Source Local Reference, Destination Port, Source Port, and DL Verification Tag. However, the mapping table is not limited to this, only the connection identification ID (SCCP connection # 0, etc.) is supported, and the connection identification ID and identification information are separately stored, so that the correspondence is held in other formats. Good. Here, all mapping tables (mapping table and identification information when the identification information is separately held) are held in the storage unit 29 so that each processing unit can read and write. Each mapping table used for processing may be held (each component includes a storage unit).

  The lower layer processing unit 28 of the Iu side processing unit 22 confirms the IP header by the IP protocol processing function, and the IP DA of the RANAP message received from the CN 4 is the address (HNB-GW 3 in FIG. 4) of itself (HNB-GW 3). IP address), and whether the IP SA is the address of CN 4 facing (in FIG. 4, described as CN IP).

  When the IP DA is its own address and the IP SA is the CN4 address, the SCTP protocol processing unit 27 of the Iu side processing unit 22 performs SCTP association (Destination Port, Source Port, and DL Verification Tag) of the RANAP message. Is a value between the opposing CN4.

  When confirming that the SCTP association is a value between the opposing CNs 4, the SCCP protocol processing unit 26 of the Iu side processing unit 22 extracts the Destination Local Reference and the Source Local Reference of the RANAP message. Then, the SCCP protocol processing unit 26 refers to the mapping table of the inter-peer correspondence 38, and searches for the identification information (RUA Context) of the RUA connection corresponding to the extracted Destination Local Reference and Source Local Reference. When the RUA Context ID corresponding to the RUA connection corresponding to the Destination Local Reference and the Source Local Reference is obtained as a search result, the SCCP protocol processing unit 26 transmits the RANAP message together with the obtained RUA Context ID to the Iuh side processing unit 21. To the RUA protocol processing unit 23.

  The RUA protocol processing unit 23 searches the mapping table of the inter-layer correspondence 37 in the storage unit 29, and identifies identification information (IP DA, IP SA, Destination Port, Source Port, and DL Verification) corresponding to the received RUA Context ID. Tag) and the RANAP message is passed to the SCTP protocol processing unit 24 together with the acquired identification information.

  The SCTP protocol processing unit 24 generates an SCTP message in which the Destination Port, the Source Port, and the DL Verification Tag are set based on the received identification information in the received RANAP message, and the generated SCTP message is received by the received IP DA and IP SA. At the same time, it is passed to the lower layer processing unit 25. The lower layer processing unit 25 generates an IP packet in which the received IP DA and IP SA are set in the received SCTP message, and transmits the generated IP packet to the destination HNBs 2-0 to 2-N. Through the above procedure, the HNB-GW 3 transfers the RANAP message received from the CN 4 to the HNBs 2-0 to 2-N.

  Next, an operation when the HNB-GW 3 transfers a message obtained by encapsulating the NAS message transmitted from the UE 1 into the RANAP message to the CN 4 will be described. The HNB-GW 3 receives a RANAP message encapsulating the NAS message transmitted from the UE 1 via the HNBs 2-0 to 2-N connected to the UE 1. The lower layer processing unit 25 of the Iuh side processing unit 21 uses the IP DA of the received message as the IP protocol processing with the IP address of the own device and the IP addresses of the HNBs 2-0 to 2-N facing the IP SA. Check if it exists.

  When the IP DA of the received message is the IP address of the own device and the IP SA is the IP address of the opposing HNBs 2-0 to 2-N, the SCTP protocol processing unit 24 sets the SCTP association included in the message. It is confirmed whether the identification information (Destination Port, Source Port, and DL Verification Tag) is a value between the opposing devices (HNB2-0 to 2-N).

  When the identification information of the SCTP association is a value between the opposing devices, the RUA protocol processing unit 23 extracts the RUA Context ID from the received message. Then, the RUA protocol processing unit 23 refers to the mapping table of the inter-peer correspondence 38 and searches for the Destination Local Reference and the Source Local Reference corresponding to the extracted RUA Context ID. When the corresponding Destination Local Reference and Source Local Reference are obtained as the search results, the RUA protocol processing unit 23 receives the received Destination Local Reference and the Source Local Reference for the received message of the protocol unit 22 on the ISC side. The data is passed to the processing unit 26.

  The SCCP protocol processing unit 26 refers to the mapping table of the inter-layer correspondence 34, and searches for the identification information of the SCTP association corresponding to the received Destination Local Reference and Source Local Reference. Then, the SCCP protocol processing unit 26 passes the received message together with the searched identification information to the SCTP protocol processing unit 27.

  The SCTP protocol processing unit 27 generates an SCTP message storing the received message based on the identification information received from the SCCP protocol processing unit 26, and the lower layer together with the IP SA and IP DA of the identification information received from the generated SCTP message. The data is passed to the processing unit 28. The lower layer processing unit 28 generates an IP packet storing the received IP SA and IP DA in the received SCTP message, and transmits the generated IP packet to the CN 4. Through the above procedure, the HNB-GW 3 transfers the RANAP message received from the UE 1 via the HNBs 2-0 to 2-N to the CN 4.

  Next, a method for creating a mapping table according to the present embodiment will be described. FIG. 5 is a chart diagram illustrating an example of a procedure for creating a mapping table according to the present embodiment. First, the HNB 2 receives the initial RANAP message (Initial UE Message: INIT) from the UE 1 to the CN 4. In practice, UE1 generates the first NAS message for CN4, and HNB2 that received the NAS message transmits it as a RANAP message that encapsulates the NAS message. However, in HNB-GW3, it is recognized as a RANAP message. Therefore, the description of the NAS protocol processing is omitted.

  At this time, since the RANB connection is not set up with the HNB-GW3, the HNB2 sends an SCTP INIT message for requesting a connection to the SCNB protocol of the HNB-GW3. The data is transmitted to a protocol processing unit (abbreviated as SCTP in FIG. 5) 24 (step S1).

  When receiving the SCTP INIT message, the SCTP protocol processing unit 24 of the HNB-GW 3 transmits an SCTP INIT-ACK message including COOKIE, which is a unique context for identifying this connection request, to the HNB 2 as a response to the message (step S44). S2). When the HNB 2 receives the SCTP INIT-ACK message, the HNB 2 transmits an SCTP COOKIE-ECHO message to the SCTP protocol processing unit 24 of the HNB-GW 3 (step S3). At this time, since the RUA connection is not set up with the HNB-GW 3, the HNB 2 encapsulates the RUA CONNECT message requesting the RUA connection into the SCTP COOKIE-ECHO message and transmits it. Also, it is assumed that the Initial UE Message received from UE1 is encapsulated in this RUA CONNECT message.

  The SCTP protocol processing unit 24 passes the received RUA CONNECT message to the RUA protocol processing unit (abbreviated as RUA in FIG. 5) 23 (step S4). The RUA protocol processing unit 23 extracts the Context ID included in the RUA CONNECT message, so that the RUA connection between the HNB 2 and the HNB-GW 3 is established.

  At this time, the SCTP association between HNB2 and HNB-GW3 has not been established yet, but HNB-GW3 uses IP SA (in this case, the address of HNB2), IP as identification information of Iuh side SCTP association 35. Information on DA (in this case, the address of HNB-GW3), Source proto, and Destination Port can be acquired by the above procedure. The SCTP protocol processing unit 24 of the HNB-GW3 determines the DL Verification Tag to be used with the HNB2, and stores the Context ID of the RUA connection and the corresponding SCTP association information (other than the UL Verification Tag). Stored as an entry in the mapping table of the inter-layer correspondence 37 (step S5).

  The RUA protocol processing unit 23 outputs a RANAP message (RNAP: Initial UE Message) encapsulating the Initial UE Message included in the received RUA CONNECT message to the SCCP protocol processing unit 26 together with the Context ID extracted from the RUA CONNECT message. (Step S6). Since the SCCP connection between HNB-GW3 and CN4 is not set, the SCCP protocol processing unit 26 determines the source local reference used in the SCCP connection between HNB-GW3 and CN4. The SCCP protocol processing unit 26 stores the correspondence between the determined source local reference and the Context ID passed from the RUA protocol processing unit 23 in the storage unit 29 as an entry in the mapping table of the inter-peer correspondence 38 (step S7). ).

  Since Destination local reference is notified from the opposite device, the SCCP protocol processing unit 26 cannot set Destination local reference in the mapping table at this point, but the mapping table is an item other than Destination local reference. As an entry.

  The SCCP protocol processing unit (abbreviated as SCCP in FIG. 5) 26 generates an SCCP CR (Connection Request) message encapsulating RNAP: Initial UE Message and passes it to the SCTP protocol processing unit 27 (step S8). At this time, since the SCTP association with the CN 4 has not been set yet, the SCCP protocol processing unit 26 transmits an SCTP INIT message to the CN 4 (step S10).

  Since the SCTP protocol processing unit 27 can determine the UL Verification Tag in the transmission direction, it determines the UL Verification Tag to be used with the CN 4, and the IP DA, IP SA, Source Port, and Destination Port between the CNs 4 are known. The STP connection information other than the DL Verification Tag and the source local reference determined by the SCCP protocol processing unit 26 are stored in the storage unit 29 as an entry in the mapping table of the inter-layer correspondence 34 (steps). S9).

  When the CN4 receives the SCTP INIT message from the SCTP protocol processing unit 27 of the HNB-GW3, it transmits an SCTP INIT-ACK message as a response (step S11). When the SCTP protocol processing unit 27 of the HNB-GW 3 receives the SCTP INIT-ACK message from the SN 4, it transmits an SCTP COOKIE-ECHO message (step S12). It is assumed that the SCCP CR message received from the SCCP protocol processing unit 26 is encapsulated in this SCTP COOKIE-ECHO message. Here, the SCCP CR message received from the SCCP protocol processing unit 26 is encapsulated in the SCTP COOKIE-ECHO message. However, the present invention is not limited to this, and the SCCP protocol processing unit is included in the SCTP INIT message transmitted in step S10. The SCCP CR message received from H.26 may be encapsulated.

  When the CN4 receives the SCTP COOKIE-ECHO message from the SCTP protocol processing unit 27 of the HNB-GW3, the CN4 extracts the encapsulated SCCP CR message and generates an SCCP CC message for notifying connection confirmation as the SCCP protocol processing. Then, the CN 4 generates an SCTP COOKIE-ACK message that encapsulates the generated SCCP CC message, and transmits the generated SCTP COOKIE-ACK message to the HNB-GW 3 (step S13). The SCTP COOKIE-ACK message includes a DL Verification Tag.

  Here, in CN4, the RANAP message (GMM (General Packet Radio Service): Authentication AND Ciphering Request) (authentication AND requesting request) R) (authentication AND ciphering request R) message (authentication request request)) (authentication AND ciphering request R) message to the SCCP CC message. (Direct Transfer) is stored. In the present embodiment, there is no restriction on the content of the RANAP message, and therefore the description of the content of the RANAP message is omitted here.

  The SCTP protocol processing unit 27 of the HNB-GW 3 establishes the SCTP association with the CN 4 by receiving the SCTP COOKIE-ACK message. The SCTP protocol processing unit 27 sets the DL Verification Tag included in the SCTP COOKIE-ACK message to the entry in the mapping table of the inter-layer correspondence 34 stored in Step S9 (DL Verification Tag is not set). As a result, the entry in the mapping table of the inter-layer correspondence 34 is completely confirmed. The SCCP CC message is extracted from the received SCTP COOKIE-ACK message, and the extracted message is passed to the SCCP protocol processing unit 26 (step S14).

  The SCCP protocol processing unit 26 extracts the Destination local reference stored in the received SCCP CC message, and stores it in the entry of the mapping table of the inter-peer correspondence 38 stored in Step S7 (Destination local reference is not set). (Step S15). This completes this entry in the mapping table for the internal peer-to-peer correspondence 38. In addition, the SCCP protocol processing unit 26 passes the RUA message encapsulating the RANAP message extracted from the SCCP CC message together with the identification information (Destination local reference and Source local reference) of the SCCP connection to the RUA protocol processing unit 23 (step S21). S16).

  The RUA protocol processing unit 23 passes the RUA message encapsulating the received RANAP message to the SCTP protocol processing unit 24 (step S17). The SCTP protocol processing unit 24 determines the UL Verification Tag of the SCTP connection corresponding to the destination HNB2. Then, the SCTP protocol processing unit 24 transmits the SCTP COOKIE-ACK message (which stores the determined UL Verification Tag) encapsulating the RUA message received from the RUA protocol processing unit 23 to the HNB 2 (step S18). . In addition, the SCTP protocol processing unit 24 sets the UL Verification Tag determined in the mapping table entry of the inter-layer correspondence 37 stored in step S5. Thereby, the entry of the mapping table of the correspondence between layers 37 can be completely confirmed.

  The RANAP message includes an RNC-ID indicating a destination and an Iu signaling connection identifier. When a normal RANAP message is transferred, the transfer device transfers the RANAP message based on the information. It is necessary to perform the decoding process. On the other hand, in the present embodiment, transfer is performed with reference to connection information of lower-layer protocols such as the RUA protocol, the SCCP protocol, and the SCTP protocol, and the decoding process of the RANAP message is unnecessary.

  Here, RANAP is described as an example of the signaling protocol. However, the present invention is not limited to this, and any signaling protocol may be used. Further, the lower protocol of the signaling protocol is not limited to the RUA protocol, the SCCP protocol, and the SCTP protocol, and any protocol may be used, and the connection information of the lower protocol is exchanged between layers as in the present embodiment. The correspondence and the correspondence between internal peers may be held.

  In this embodiment, the correspondence between layers and the correspondence between internal peers are held as a mapping table. However, if the same information can be held, it can be handled using a format other than the table format. May be held.

  As described above, in this embodiment, the HNB-GW 3 is configured such that the protocol of the lower layer of the RANAP protocol corresponds to the connection between the Iu side (RUA connection and SCTP association), and the connection between the Iuh side (SCCP connection and SCTP). Association) and Iu-side connection (RUA connection) and Iuh-side connection (SCCP connection). Based on the held correspondence, the lower-layer protocol of the RANAP protocol Was transferred. Therefore, the RANAP message can be transferred without performing termination processing. Also, the signaling message can be transferred when the transfer source and the transfer destination use different protocols.

Embodiment 2. FIG.
Next, a packet transfer method according to the second embodiment of the present invention will be described. The configuration of the communication system according to the present embodiment is the same as the configuration of the communication system according to the first embodiment. The configuration of the HNB-GW in the present embodiment is the same as that of the HNB-GW 3 in the first embodiment. The protocol stack of the present embodiment is the same as the protocol stack of the first embodiment. Hereinafter, differences from the first embodiment will be described.

  In the first embodiment, a mapping table indicating correspondence between connections between protocols is created based on the connection identification information of each protocol, and the mapping table is searched based on the identification information. In this embodiment, in order to facilitate the search of the mapping table, logical identification information that does not depend on the protocol is introduced in the HNB-GW.

  Information identifying the SCTP association includes a 4-byte destination IP address (IP SA), a 4-byte source IP address (IP DA), a 2-byte SCTP destination port number (Source port), and a 2-byte SCTP. A transmission source port number (Destination port) and a 4-byte Verification Tag (DL Verification Tag / UL Verification Tag).

  The information for identifying the SCCP connection is a 3-byte Destination Local Reference and a 3-byte Source Local Reference.

  The information for identifying the RUA connection is a 3-byte Context ID. As described above, the contents and amount of information for identifying the connection differ depending on the protocol. In this embodiment, in order to simplify the correspondence information between connections, logical identification information common in the apparatus that links these identification information to each other is introduced. Since the minimum unit of connection is an SCCP connection or an RUA connection, the logical identification information is 3 bytes here. The logical identification information is not limited to 3 bytes and may be any number of bytes. Any method may be used for setting the logical identification information. For example, when the connection information is stored for the first time, the connection information and the logical identification information become one-to-one for the connection that is the smallest unit. Logical identification information is assigned.

  FIG. 6 is a diagram illustrating an example of correspondence between logical identification information and identification information of each connection. As shown in FIG. 6, for example, the logical identification information # 0 (3-byte numerical value) includes Iuh side SCTP association information # A0, Iuh side RUA connection information # B0, and Iu side SCCP connection information # C0. And SCu association information # D0 on the Iu side. Similarly, the logical identification information # 1 to # 5 corresponds to the connection information of each connection.

  The Iuh side SCTP association information # A0 to # A2 includes a 4-byte destination IP address, a 4-byte transmission source IP address, a 2-byte SCTP destination port number, and a 2-byte SCTP transmission source port number. Although the 4-byte DL Verification Tag / UL Verification Tag, these pieces of information are collectively shown as # A0 to # 2. The same applies to the SC side association information # D0 on the Iu side. For the Iu-side SCCP connection information # C0 to # C5, information of 3 bytes of Destination Local Reference and 3 bytes of Source Local Reference is collectively shown as # C0 to # C5.

  In order to perform processing more simply, the correspondence of the identification information of each connection can be held together as one large mapping table illustrated in FIG. 6 without using the logical identification information. On the other hand, in consideration of the independence and expandability of the protocol, a method is also conceivable in which the processing units of each protocol are distributed to hold information. In this case, for example, the SCTP protocol processing unit 24 of the Iuh side processing unit 21 holds the correspondence between the logical identification information and the Iuh side SCTP association information as a mapping table, and the RUA protocol processing unit 23 of the Iuh side processing unit 21 The correspondence between the logical identification information and the Iuh side RUA connection information is held as a mapping table, and the SCCP protocol processing unit 26 of the Iu side processing unit 22 holds the correspondence between the logical identification information and the Iu side SCCP connection information as a mapping table. The SCTP protocol processing unit 27 of the Iu side processing unit 22 holds the correspondence between the logical identification information and the Iu side SCTP association information as a mapping table.

  In consideration of independence and extensibility from the viewpoints of the Iu side and the Iuh side, the Iuh side processing unit 21 maps the correspondence between the logical identification information, the Iuh side SCTP association information, and the Iuh side RUA connection information. And the Iu side processing unit 22 may hold the correspondence between the logical identification information, the Iu side SCCP connection information, and the Iu side SCTP association information as a mapping table. The configuration of the mapping table can be flexibly changed according to the situation. By holding the mapping table by these methods, each protocol processing unit obtains logical identification information from the connection information of its own protocol, and further obtains connection information of another protocol corresponding to the logical identifier, Connection information of other protocols corresponding to connection information of other protocols can be created.

  However, it should be noted that when a plurality of connections are multiplexed in one connection, connection identification information of a protocol that uniquely corresponds to the connection identification information of the corresponding protocol may not be mapped. For example, when the SCTP protocol processing unit 27 of the Iu side processing unit 22 obtains the corresponding SCCP connection information from the SCTP association information of the received message, the Iu side SCCP connection information includes a plurality of Iu side SCTP association information # C0. Since it corresponds to ~ # C5, the logical identification information cannot be specified as one. In this case, the SCCTP protocol processing unit 26 specifies the logical identification information using the Destination Local Reference and the Source Local Reference of the received message. In the reverse direction, it is obvious that the logical identification information can be uniquely specified.

  If the relationship is clear, such as SCCP and SCTP and RUA and SCTP, the table search method as described above may be determined for each protocol. In addition, when the multiplex relationship is unknown or more generalized, a flag for indicating that the logical identification information cannot be uniquely specified due to being multiplexed is added to each connection information. Good.

  Next, the mapping operation of the connection between the layers of the HNB-GW3 of the present embodiment will be described by taking as an example the case of transferring the RANAP message transmitted from the CN4. Here, a case will be described as an example in which each protocol processing unit has a logical identification information and a connection mapping table of the corresponding protocol. Further, it is assumed that the identification information of each protocol corresponds to that illustrated in FIG.

  In the HNB-GW 3, the lower layer processing unit 28 and the SCTP protocol processing unit 27 of the Iu side processing unit 22 extract SCTP association information from the received message. Assume that the SCTP association information is # D0. The SCTP protocol processing unit 27 cannot specify the logical identification information corresponding to this SCTP association, and therefore passes the received message to the SCCP protocol processing unit 26 without specifying the logical identification information. The SCCP protocol processing unit 26 extracts SCCP connection information (Destination Local Reference and Source Local Reference) from the message, and obtains logical identification information based on the extracted SCCP connection information. For example, if the extracted SCCP connection information is # C1, the SCCP protocol processing unit 26 obtains # 1 as logical identification information.

  In the case of the first embodiment, the SCCP protocol processing unit 26 searches for the corresponding IUA-side RUA connection information by using the extracted Iu-side SCCP connection information as a key. IU side RUA connection information is searched using the information as a key. After that, the RUA protocol processing unit 23 searches for the SCTP association information on the Iuh side using the logical identification information as a key. Based on the search result, an RUA message, an SCTP message, and an IP packet are generated based on the message received from the SCCP protocol processing unit 26 and transferred to the opposing HNB 2. As described above, in this embodiment, the search key is shortened and the structure of the search database is the same for each table, so that the search efficiency is improved and the transfer efficiency can be improved. The operations of the present embodiment other than those described above are the same as those of the first embodiment.

  As described above, in this embodiment, connection information of each protocol is held in association with logical identification information, and connection information of another protocol corresponding to the protocol is searched using the logical identification information. Therefore, the same effect as in the first embodiment can be obtained, and the search key can be shortened compared with the first embodiment, the search efficiency can be improved, and the transfer efficiency can be improved. Furthermore, since the correspondence of each protocol connection can be comprehensively handled using the logical identification information as a key, it is easy to manage.

Embodiment 3 FIG.
Next, a packet transfer method according to the third embodiment of the present invention will be described. The configuration of the communication system according to the present embodiment is the same as the configuration of the communication system according to the first embodiment. The configuration of the HNB-GW in the present embodiment is the same as that of the HNB-GW 3 in the first embodiment. The protocol stack of the present embodiment is the same as the protocol stack of the first embodiment. Hereinafter, differences from the first embodiment or the second embodiment will be described.

  In the second embodiment, the mapping table using the logical identification information is held for each protocol. Here, a case where the mapping table is held for each interface (Iu side and Iuh side) will be described. In this embodiment, the Iuh side processing unit 21 holds the correspondence between the logical identification information, the Iuh side SCTP association information, and the Iuh side RUA connection information as a mapping table, and the Iu side processing unit 22 stores the logical identification information. And Iu side SCCP connection information and Iu side SCTP association information are stored as a mapping table.

  The mapping operation of the connection between the HNB-GW3 layers of this embodiment will be described by taking as an example the case of transferring the RANAP message transmitted from CN4. Here, a case will be described as an example in which each protocol processing unit has a logical identification information and a connection mapping table of the corresponding protocol. Further, it is assumed that the identification information of each protocol corresponds to that illustrated in FIG.

  In the HNB-GW 3, the lower layer processing unit 28 and the SCTP protocol processing unit 27 of the Iu side processing unit 22 extract SCTP association information from the received message. Assume that the SCTP association information is # D0. Since the SCTP protocol processing unit 24 cannot specify the logical identification information corresponding to this SCTP association, the SCTP protocol processing unit 24 passes the received message to the SCCP protocol processing unit 26 without specifying the logical identification information. The SCCP protocol processing unit 26 extracts SCCP connection information (Destination Local Reference and Source Local Reference) from the message, and obtains logical identification information based on the extracted SCCP connection information. For example, if the extracted SCCP connection information is # C1, the SCCP protocol processing unit 26 obtains # 1 as logical identification information.

  In the second embodiment, the SCCP protocol processing unit 26 searches for the Ruh connection information on the Iuh side and the SCTP association information on the Iuh side using the logical identification information as a key. In this embodiment, the SCCP protocol processing unit 26 retrieves the logical identification information. It is possible to simultaneously search the Iuh side RUA connection information and the Iuh side SCTP association information as a key. The operations of the present embodiment other than those described above are the same as those of the second embodiment.

  Thus, in this embodiment, the correspondence between the logical identification information and each connection information is held as a mapping table for each interface using the logical identification information. Therefore, the same effect as in the second embodiment can be obtained, and the search efficiency is further improved because the number of searches is reduced by simultaneously searching a plurality of connection information. In addition, transfer efficiency can be improved by improving search efficiency.

Embodiment 4 FIG.
Next, a packet transfer apparatus according to the fourth embodiment of the present invention will be described. In the present embodiment, the HNB 2 described in the first embodiment will be described as an example of the packet transfer apparatus according to the present invention. The HNB 2 performs the same operation as the packet transfer method of the HNB-GW 3 described in the first to third embodiments.

  The HNB 2 stores the correspondence between the connection information of the Ruh protocol on the Iuh side shown in FIG. 2 and the RRC connection information of the RRC protocol on the Uu side as a mapping table, and uses the mapping table to change the RUA protocol of the received message. The RRC connection information corresponding to the connection information is obtained, and the RUA connection information corresponding to the connection information of the RRC connection information of the received message is obtained. As a result, the HNB 2 can transfer the RANAP message and the NAS message. Any of the methods in the first to third embodiments may be used as the mapping table holding method and the connection information searching method.

  As described above, even when both the interfaces (Uu side and Iuh side) do not include the same protocol, the operations of the first to third embodiments can be applied, and the same as the first to third embodiments. The effect of can be obtained.

  As described above, the packet transfer apparatus, the communication system, and the packet transfer method according to the present invention are useful for a packet transfer apparatus that transfers a signaling message, and are particularly suitable when using protocols with different transfer sources and transfer destinations. ing.

1 UE
2 HNB
3 HNB-GW
4 CN
5 Security Gateway
6 HMS
11 Uu interface 12 Iuh interface 13 Iu interface 14 TR-069 interface 21 Iuh side processing unit 22 Iu side processing unit 23 RUA protocol processing unit 24 SCTP protocol processing unit 25 Lower layer processing unit 26 SCCP protocol processing unit 27 SCTP protocol processing unit 28 Lower layer processing unit 29 Storage unit 31 Iu side SCTP association 32 Iu side SCCP connection 33 RANAP connection 34, 37 Inter-layer correspondence 35 Iuh side SCTP association 36 Iuh side RUA connection 38 Inter peer correspondence

Claims (16)

A packet transfer device that connects to two or more communication devices and transfers a signaling message generated based on a signaling protocol received from the communication device to another communication device,
Protocol processing means for performing transmission / reception processing with the communication device based on a lower layer protocol of the signaling protocol, and acquiring connection identification information as connection information when setting a connection based on the lower layer protocol; ,
Storage means for holding the connection information;
With
The protocol processing means stores the connection information in the storage means, and transfers the signaling message based on the connection information and identification information of the lower layer protocol extracted from the received signaling message;
A packet transfer apparatus. The communication device includes a first communication device and a second communication device,
The protocol processing means includes
Transmission / reception processing is performed with the first communication device based on a first protocol that is a lower layer protocol of the signaling protocol, and when setting a connection based on the first protocol, identification information of the connection is obtained. First protocol processing means to obtain as first connection identification information;
Transmission / reception processing is performed with the second communication device based on a second protocol that is a lower layer protocol of the signaling protocol, and when setting a connection based on the second protocol, identification information of the connection is obtained. Second protocol processing means to obtain as second connection identification information;
With
One or more of the first protocol processing means and the second protocol processing means may use the first connection identification information and the second connection identification information corresponding to the same connection as the connection information. Are stored in the storage means in association with each other.
The packet transfer apparatus according to claim 1. The first protocol processing means and the second protocol processing means extract the information to be stored as the connection information from the received packet until the connection setting by its protocol is completed, and extract the information Storing information as the connection information;
The packet transfer apparatus according to claim 2, wherein: The first protocol and the second protocol are different from each other,
The packet transfer apparatus according to claim 2 or 3, wherein The first protocol is an RUA protocol and the second protocol is an SCCP protocol;
The packet transfer apparatus according to claim 4, wherein: Perform transmission / reception processing with the first communication device based on a first lower protocol, which is a lower layer protocol than the first protocol, and when setting a connection based on the first lower protocol, First lower protocol processing means for acquiring connection identification information as first lower connection identification information;
Further comprising
The first protocol means or the first lower protocol processing means associates the first connection identification information corresponding to the same connection and the first lower connection identification information as the connection information in association with the first connection means. Store in storage means,
The first lower protocol processing means transfers the signaling message based on the identification information of the connection of the first lower protocol extracted from the received signaling message and the connection information.
The packet transfer apparatus according to any one of claims 2 to 5, wherein The first lower-level protocol processing means extracts information to be stored as the connection information from the received packet until the connection setting by its protocol is completed, and stores the extracted information as the connection information To
The packet transfer apparatus according to claim 6. The first lower protocol is an SCTP protocol.
The packet transfer apparatus according to claim 6 or 7, wherein: Perform transmission / reception processing with the second communication device based on a second lower protocol, which is a lower layer protocol than the second protocol, and when setting a connection based on the second lower protocol, Second lower protocol processing means for acquiring connection identification information as second lower connection identification information;
Further comprising
The second protocol processing means or the second lower protocol processing means associates the second connection identification information corresponding to the same connection and the second lower connection identification information as the connection information. Storing in the storage means;
The second lower protocol processing means transfers the signaling message based on the identification information of the connection of the second lower protocol extracted from the received signaling message and the connection information.
The packet transfer apparatus according to any one of claims 2 to 8, wherein The second lower-level protocol processing means extracts information to be stored as the connection information from the received packet until the connection setting by its protocol is completed, and stores the extracted information as the connection information To
The packet transfer apparatus according to claim 9. The second lower protocol is an SCTP protocol.
The packet transfer apparatus according to claim 9 or 10, wherein: The protocol processing means stores, as the connection information, logical identification information independent of a protocol for identifying a connection and connection identification information of each protocol, and receives the received signaling using the logical identification information. Obtaining logical identification information corresponding to the connection identification information extracted from the message, and obtaining connection identification information corresponding to the same connection based on the logical identification information;
The packet transfer apparatus according to any one of claims 2 to 11, wherein It has a function as HNB-GW,
The first communication device is HNB,
The second communication device is a device in the core network,
The packet transfer apparatus according to any one of claims 2 to 12, wherein Has the function of HNB,
The first communication device is a wireless terminal,
The second communication device is an HNB-GW.
The packet transfer apparatus according to any one of claims 2 to 12, wherein A packet transfer apparatus according to claim 1;
HNB connected to the packet device;
A core network connected to the packet device;
With
The packet transfer apparatus transfers a signaling message generated based on a signaling protocol between the HNB and the core network.
A communication system. A packet transfer method in a packet transfer device that connects to two or more communication devices and transfers a signaling message generated based on a signaling protocol received from the communication device to another communication device,
A protocol processing step of performing transmission / reception processing with the communication device based on a lower layer protocol of the signaling protocol, and acquiring connection identification information as connection information when setting a connection based on the lower layer protocol; ,
A storage step for holding the connection information;
A transfer step of transferring the signaling message based on the identification information of the connection of the lower layer protocol extracted from the received signaling message and the connection information held in the storing step;
And a packet transfer method.

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