KR100899205B1 - Method for routing by virtual signal link-set in signaling gateway and signaling gateway thereof - Google Patents

Abstract

The present invention relates to a routing processing method using a virtual signal link set in a signaling gateway and a signaling gateway for the same.

The present invention provides a message routing method in SG or STP, which is a signal relay node located between two nodes for message communication between an SCCP final translation signal node and a SIGTRAN SUA signal node in a 2G mobile communication network.

The present invention can be expected to modify the SCCP stack of the TDM SEP and reduce the national data work and maintenance costs by changing the network operated by the existing M3UA interworking method to the SUA interworking method.

Signaling Gateway, Routing, Virtual Signal Linkset, Incoming Signaling Point, SCCP, MTP3

Description

Routing method using virtual signal link set in signaling gateway and signaling gateway therefor {Method for Routing by Virtual Signal Link-Set in Signaling Gateway and Signaling Gateway Thereof}

The present invention relates to a gateway system, and more particularly, to a routing processing method using a virtual signal link set in a signaling gateway.

The gateway system is located between the public switched telephone network (hereinafter referred to as 'PSTN') and the packet network (IP network) to provide voice and video services using voice and video codec conversion and signaling conversion functions. It is an important component of next generation network.

The gateway system includes a media gateway, a trunk gateway, a video media gateway, and a signaling gateway (hereinafter, referred to as 'SG').

The message transmission method between the final translation signal node of the Signaling Connection Control Part (hereinafter referred to as 'SCCP') of the existing 2G mobile communication network and the signal node of the SIGTRAN network is described in detail with reference to FIG. The M3UA interworking method in which the MTP3 User Adaptation Layer (STP) stack and the M3UA stack of the SIGTRAN network interwork is used.

1 is a view for explaining the M3UA interworking method of a conventional 2G mobile communication network.

In the message transfer part level 3 (hereinafter, referred to as 'MTP3') of the SG 300, routing is performed using an incoming signaling point of the MTP3 header, and in case of a message to be transmitted to the SIGTRAN network, the SG 300 Transmit to M3UA to SIGTRAN network.

As shown in FIG. 1, the M3UA interworking method does not go through the SCCP, the layer above the MTP3 even if the service indicator is SCCP since the incoming signaling point of the MTP3 is not the signal point of the SG 300. Therefore, SCCP stack processing is to be performed at the signal node of the SIGTRAN network.

When processing the SCCP stack in the signal node of the SIGTRAN network, there is a problem that the processing load, equipment price and maintenance cost of the signal node of the SIGTRAN network takes a lot.

In order to improve this, the proposed method is a SCCP User Adaptation Layer (hereinafter referred to as SUA) interworking that can perform processing on the SCCP stack in the SG as described below.

2 is a view for explaining a SUA interworking method of a conventional modified 2G mobile communication network.

When a message is transmitted from the TDM SEP (switch) 100 to the SUA signal node (SUA SEP) 400 of the SIGTRAN network, the MTP3 incoming signaling point of the message becomes the signal point of the SUA signal node 400.

The SG 300 needs to receive the message and transmit it to the SUA signal node 400 via the SCCP and SUA stacks, but cannot transmit the message from the MTP3 to the SCCP of the SG 300 according to the following MTP3 routing rule.

The conditions for transmitting a message to SCCP in which MTP3 is a higher layer are as follows (ITU-T Q.704).

The MTP3 message cannot be sent from the MTP3 to the SCCP unless both the destination point code (DPC) of the MTP3 message must match its own signaling point and the service indicator of the MTP3 message is SCCP. have.

In order to satisfy the above conditions, the SCCP stack of all existing TDM SEP 100 must be modified, and there is a problem that the station data work and the maintenance cost thereof are increased.

In order to solve such a problem, the present invention is to provide a routing processing method using a virtual signal link set in the signaling gateway and a signaling gateway for the same.

According to an aspect of the present invention, a signaling gateway according to a feature of the present invention extracts an incoming signal point in a header of a received message, and if the extracted incoming signal point is not its own signal point, the extracted incoming call from the pre-stored routing table. A message protocol stack for searching for a signal point and transmitting the received message to a first signal route corresponding to the extracted incoming signal point; And receiving the received message from the message protocol stack through an upper and lower layer communication path or a virtual signal link set, and transmitting the received message to a second signal route corresponding to an incoming signal point in header information of its own protocol stack. It includes a signal protocol stack.

Routing processing method according to a feature of the invention comprises the steps of (a) extracting the incoming signal point in the received message; (b) determining whether the extracted incoming signal point is a signal point of its own, and searching a pre-stored routing table to determine whether a signal point state corresponding to the extracted incoming signal point is normal when the extracted incoming signal point is not its own signal point; And (c) if the signal point state corresponding to the extracted incoming signal point is normal, transmitting the received message to a higher protocol stack corresponding to the extracted incoming signal point through a virtual signal link set. .

According to the above-described configuration, the present invention can expect the effect of reducing the SCCP stack modification of the TDM SEP and the station data work and maintenance costs according to the change of the network operated by the existing M3UA interworking method to the SUA interworking method. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, “block”, etc. described in the specification mean a unit that processes at least one function or operation, which is hardware or software or a combination of hardware and software. It can be implemented as.

3 is a diagram for describing a SUA interworking method capable of processing an SCCP stack in an SG according to an embodiment of the present invention.

An embodiment of the present invention provides a message routing method in an STP 200 or an SG 300, which is a signal relay node located between two nodes for message communication between an SCCP final translation signal node and a SIGTRAN SUA signal node in a 2G mobile communication network. do.

In the embodiment of the present invention, after performing SCCP translation in the TDM SEP 100, the destination node is set to the SG 300 so that the MTP3 destination signaling point of the message becomes the SG 300 and the SCCP incoming signal point is the SUA signal node 400. Let be the signal point of. Accordingly, the MTP3 310 satisfies a condition for transmitting a message to the upper layer SCCP 320.

The SCCP translation message is transmitted to the SCCP 320 via the MTP3 310 of the SG 300 which is the SCCP receiving node. Since the incoming signal point of the SCCP 320 is the SUA signal node 400, the SG 300 is transmitted. Is sent from the SCCP 320 to SUA.

The specification number and function of the protocol stack of the present invention are as follows.

MTP1 (Q.702, Message Transfer Part Level 1) defines the physical characteristics of the SS7 signaling link.

MTP2 (Q.703, Message Transfer Part Level 2) is responsible for sending and receiving messages with neighboring signal nodes.

MTP3 (ITU-T Q.704 ~ 708, Message Transfer Part Level 3) 310 is responsible for signaling point state management and signaling message routing functions of SS7 signaling network.

SCCP (ITU-T Q.711 to 718, Signaling Connection Control Part) 320 performs GT translation (subscriber phone number-> signaling point) and manages the status of subsystems above SCCP.

SCTP (RFC2960, Stream Control Transmission Protocol) is a protocol for maintaining transmission reliability of SS7 network in IP packet network and performs message loss check, message redundancy check, message retransmission and message flow control.

M3UA (RFC3332, MTP3 User Adaptation Layer) is responsible for message relaying and message routing between the MTP3 stack and the MTP3 upper layer through the IP network.

SUA (RFC3868, SCCP User Adaptation Layer) is in charge of message relay and message routing between SCCP stack and upper layer of SCCP through IP network.

In order to solve the problems of the prior art, an embodiment of the present invention enables a signal route configuration using a virtual signal linkset and a virtual signal linkset between the MTP3 310 and the SCCP 320 so that the MTP3 310 can be configured to have its own. The message is transmitted to the SCCP 320 even if the message has an incoming signal point other than the signal point.

Next, a configuration between MTP3 and SCCP of the SG 300 for configuring a virtual signal link set will be described with reference to FIG. 4.

4 is a view for explaining the configuration between the MCP3 and SCCP of the SG for configuring the virtual signal link set according to an embodiment of the present invention.

When the MTP3 incoming signal point of the received message coincides with its own signal point, the MTP3 310 transmits the same to the SCCP 320 through the upper and lower layer communication paths in the same manner as before. That is, as shown in Figure 3, the existing upper and lower layer communication path MTP1-> MTP2-> MTP3 (310) of the SG (300)-> SCCP (320)-> SUA-> SCTP-> IP-> Ethernet-> Ethernet of the SUA signal node 400-> IP-> SCTP-> SUA-> S7UP.

The MTP3 310 sends a message via the virtual signal linkset to the SCCP 320 when the MTP3 incoming signaling point needs to send a message to the SUA signal node 400 via the SCCP 320 that does not match its own signaling point. To send. Subsequently, the SCCP 320 of the SG 300 receiving the message analyzes the SCCP header information and transmits the message to the SUA signal node 400 using an incoming signal point and a subsystem in the SCCP header information.

Next, an internal configuration of the MTP3 310 will be described in detail with reference to FIG. 5.

Here, MTP3 310 may be described in another term, a message protocol stack.

5 is a block diagram schematically illustrating an internal configuration of MTP3 of an SG for configuring a virtual signal linkset according to an embodiment of the present invention, and FIG. 6 is a diagram illustrating an example of an MTP3 routing table according to an embodiment of the present invention. Drawing.

The MTP3 310 according to an embodiment of the present invention includes an incoming signal point extractor 312, an MTP3 routing table 314, a first signal point state checker 316, a virtual signal linkset control unit 318, and a routing failure. A processing unit 319 is included.

The incoming signal point extractor 312 extracts the incoming signal point from the header of the received message.

As shown in FIG. 6, the MTP3 routing table 314 stores an incoming signaling point, a signal route to transmit a message, and state information of the signaling point.

The MTP3 routing table 314 may enter a specific value (SCCP) to send a message to the SCCP 320 over the virtual signal linkset.

The first signal point state checker 316 receives the MTP3 network management message for the SIGTRAN network signal point from the SCCP 320 and stores the state information of the signal point via the SCCP 320 in the MTP3 routing table 314. do.

The first signal point state checker 316 generates and transmits an MTP3 network management message for the TDM network signal point indicating whether the signal point via the MTP3 310 is normal or not, to the SCCP 320.

The virtual signal linkset controller 318 determines whether the extracted incoming signal point is its own signal point, and transmits the received message to the SCCP 320 through the existing formed upper / lower layer communication path. do.

The virtual signal linkset controller 318 determines the incoming signal point search in the MTP3 routing table 314 when determining that the extracted incoming signal point is not its own signal point, and when the incoming signal point search is successful, the virtual signal linkset controller 318 corresponds to the incoming signal point. Check the signal point status.

The virtual signal linkset control unit 318 transmits a message from the MTP3 routing table 314 to the signal route corresponding to the incoming signal point when the signal point state is normal.

The routing failure processing unit 319 processes the routing failure of the message when the incoming signal point search is not successful in the MTP3 routing table 314 or when the signaling point state is not normal.

Next, an internal configuration of the SCCP 320 will be described in detail with reference to FIG. 7.

Here, SCCP 320 may be described in another term, signal protocol stack.

7 is a block diagram schematically illustrating the internal configuration of the SCCP of the SG for configuring a virtual signal link set according to an embodiment of the present invention.

SCCP 320 according to an embodiment of the present invention includes a virtual signal link set matching unit 322, the second signal point state check unit 324 and the message conversion unit 326.

The virtual signal linkset matching unit 322 manages the signal links, signal linksets and signal points defined in ITU-T Q.704, and transmits the SCCP stack and messages to form a virtual signal linkset with the MTP3 310. Function.

The second signal point state checker 324 receives the MTP3 network management message for the TDM network signal point from the MTP3 310 and checks whether the signal point via the MTP3 310 is normal.

The second signal point state checker 324 generates and transmits an MTP3 network management message for the SIGTRAN network signal point indicating whether the signal point via the SCCP 320 is normal or not, to the SCCP 320.

The message converter 326 converts the received message into a message format transmitted from the SCCP 320 to the higher protocol stack to transmit the received message to the SUA. The SUA generates the SUA header by referring to the SCCP address part in the message received from the SCCP 320 and attaches the generated SUA header to the message and transmits the message to the SIGTRAN network.

The SUA converts a message received from the SIGTRAN network into a message format transmitted from the SCCP higher protocol stack to the SCCP 320 and transmits the message to the SCCP 320 for transmission to the SCCP 320.

The message conversion unit 326 generates an SCCP header with reference to the SUA address portion in the message received from the SUA, and adds the generated SCCP header to the message to transmit to the TDM network. Here, the transmission and reception message format between the SCCP 320 and the SCCP higher protocol stack is defined in ITU-T Q.711, and the interworking method between the SCCP 320 and the SUA is defined in the RFC3868 standard.

8 is a diagram illustrating a flow for transmitting a message from the MTP3 of the SG to the SCCP according to an embodiment of the present invention.

In FIG. 8, it is assumed that the service identifier of the MTP3 message is the SCCP 320 for convenience of description.

When the incoming signal point extractor 312 receives the message, the incoming signal point extractor 312 extracts the incoming signal point in the MTP3 header (S100).

The virtual signal link set control unit 318 determines whether the extracted incoming signal point is its own signal point (S102), and if it is its own signal point, the received message to the SCCP 320 through the existing upper and lower layer communication paths. It transmits (S104).

If it is determined that the extracted incoming signal point is not its own signal point, the virtual signal linkset control unit 318 searches the MTP3 routing table 314 to check whether the signal point state is normal (S106, S108, S110). .

When the signal point state is normal, the virtual signal linkset controller 318 transmits a message to the corresponding signal route. When the incoming signal point is 100 or 200, the virtual signal linkset controller 318 transmits the message to the MTP2 (S112, S114). It is transmitted to the SCCP 320 through the link set (S112, S116).

If the extracted incoming signal point is not found in the MTP3 routing table 314 or the signal point state is not normal, the virtual signal link set control unit 318 fails the routing process through the routing failure processing unit 319 (S118).

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiments of the present invention, a recording medium on which the program is recorded, and the like. Such implementations may be readily implemented by those skilled in the art from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a view for explaining the M3UA interworking method of a conventional 2G mobile communication network.

2 is a view for explaining a SUA interworking method of a conventional modified 2G mobile communication network.

3 is a diagram for describing a SUA interworking method capable of processing an SCCP stack in an SG according to an embodiment of the present invention.

4 is a view for explaining the configuration between the MCP3 and SCCP of the SG for configuring the virtual signal link set according to an embodiment of the present invention.

5 is a block diagram schematically showing the internal configuration of the MTP3 of the SG for configuring the virtual signal link set according to an embodiment of the present invention.

6 is a diagram illustrating an example of an MTP3 routing table according to an embodiment of the present invention.

7 is a block diagram schematically illustrating the internal configuration of the SCCP of the SG for configuring a virtual signal link set according to an embodiment of the present invention.

8 is a diagram illustrating a flow for transmitting a message from the MTP3 of the SG to the SCCP according to an embodiment of the present invention.

Claims (7)

Extracts an incoming signaling point in a header of a received message, and if the extracted incoming signaling point is not its own signal point, searches for the extracted incoming signaling point in a pre-stored routing table to search for the first incoming signal point corresponding to the extracted incoming signaling point; A message protocol stack for transmitting the received message to the client; And A signal for receiving the received message from the message protocol stack through an upper or lower layer communication path or a virtual signal linkset, and transmitting the received message to a second signal route corresponding to an incoming signal point in header information of its own protocol stack. Protocol stack Signaling gateway comprising a. According to claim 1, The message protocol stack, An incoming signal point extracting unit for extracting the incoming signal point in the header of the received message; A routing table for storing a plurality of incoming signal points, a signal route corresponding to each incoming signal point, and state information of each incoming signal point; Receiving a first network management message indicating the signaling point status of the IP network to grasp the status information of the signaling point via the IP network, and generating and transmitting a second network management message indicating the signaling point status of the wired network Point condition checking unit; And When the extracted incoming signal point is not the own signal point, the extracted incoming signal point is searched in the routing table; when the search is successful, the state of the signal point corresponding to the extracted incoming signal point is checked and the signal point state is normal. A virtual signal link set control unit for transmitting the received message to the upper protocol stack which is a signal route corresponding to the extracted incoming signal point through the virtual signal link set. Signaling gateway comprising a. According to claim 1, The signal protocol stack, A virtual signal linkset matching unit configured to manage a signal linkset and a signal point and transmit a message protocol stack and a message to configure the virtual signal linkset; A first network management message indicating a signaling point state of an IP network is generated and transmitted to the message protocol stack, and a second network management message indicating a signaling point state of a wired network is received to identify state information of a signaling point via a wired network. A second signal point state checking unit; And A message conversion unit converting the received message into a message format for transmitting to a higher protocol stack and transmitting the message to the second signal route Signaling gateway comprising a. According to claim 1, If the extracted incoming signal point is not its own signal point, the message protocol stack checks whether a signal point state corresponding to the extracted incoming signal point is normal in the routing table, and transmits the received message to the virtual signal link set. Signaling gateway characterized by transmitting to a signaling protocol stack. (a) extracting an incoming signal point in the received message; (b) determining whether the extracted incoming signal point is a signal point of its own, and searching a pre-stored routing table to determine whether a signal point state corresponding to the extracted incoming signal point is normal when the extracted incoming signal point is not its own signal point; And (c) if the signal point state corresponding to the extracted incoming signal point is normal, transmitting the received message to a higher protocol stack corresponding to the extracted incoming signal point through a virtual signal link set; Routing processing method comprising a. The method of claim 5, In step (b), Transmitting the received message to an upper protocol stack or a lower protocol stack through the upper and lower layer communication paths when the extracted incoming signal point is the own signal point. Routing processing method further comprising. The method of claim 5, In step (b), If the signal point state corresponding to the extracted incoming signal point is not normal, processing as a routing failure Routing processing method further comprising.

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