KR100337297B1 - Signaling Traffic Load Sharing Method Between Combined Linkset In No.7 Network - Google Patents

Abstract

To manage the signal traffic in the combined linkset in No.7 signal network, the combined linkset is regarded as a single signal linkset virtually to provide an equal signal traffic load between the signal links in the signal linkset constituting the combined linkset. The present invention relates to a signal traffic load sharing method in a combined link set in a number seven signal network.

The present invention provides a process for defining a combined link set comprising an individual signal link set constituting the combined link set as a virtual signal link set; Sharing the traffic load with the signal link in the virtual signal link set and transmitting it to the next signal point; Determining whether a non-available link exists due to a failure of the signal link in the virtual signal link set; Switching load sharing traffic to an available signal link if the unavailable signal link exists; Converting and returning the load sharing traffic to the entire signal link upon entering an available state due to failure recovery of the unusable signal link; If the message to be routed to the signal link is a message prohibiting routing to a specific signal point, performing a non-availability process for the corresponding route, and then routing the message through the available individual signal linksets; And if the message to be routed to the signal link is a transfer permission message, routing the message through an available combined link set.

Thus, by sharing the signal traffic between the signal links in the combined linkset, load sharing is provided without the occurrence of signal traffic on a particular signal link in the combined linkset or no signal traffic on the particular signal link, thereby providing load sharing. Signal traffic is evenly distributed over the signal link, providing stability and reliability for the signal traffic.

Description

Signaling Traffic Load Sharing Method Between Combined Linkset In No.7 Network in No.7 Signaling Network

The present invention relates to a method for managing signal traffic in a combined linkset in a No.7 signal network. More particularly, the present invention relates to a method for managing a combined linkset by virtually considering the combined linkset as one signal linkset. The present invention relates to a signal traffic load sharing method in a combined link set in a number seven signal network for providing an equal signal traffic load between signal links in a signal link set.

In general, the No.7 signaling system, which is a common line signaling system standardized by the International Telecommunication Standardization Division (ITU-T) of the International Telecommunication Union, provides various kinds of control signals for providing call connection and various communication services or operating and managing communication networks between subscribers. As a signaling method for transmitting the message, a message transfer unit (MTP: Message Transfer), which is a network service unit that distributes signal transmission control, error correction, and security measures of a signal network, in order to increase versatility, as shown in FIG. Part), and information related to circuit-related / unrelated signal information, as well as information between a special center of a communication network and an exchange station, by means of the MTP. Signaling Connection Control Part (SCCP) provided, depending on the application field such as telephone exchange and data exchange Individually designed telecommunications network user with basic functions for controlling 64 Kbps transparent channels or lower non-transparent channels for voice and non-voice services, plus user service functions beyond those provided by telephone user units Control the ISUP (ISDN User Part), the non-line related signaling information, the definition of parameters and primitives, the matching of other functions, and the Transaction Capability (TCAP), and general telephone call services. Call line management functions such as allocation, operation and retrieval of call lines, continuity check, blocking and unblocking of call lines, using MTP to transmit signaling message information to the other party. Telephony user unit that provides basic functions such as reset and additional service functions (TUP: Tele phone User Part), and a mobile communication network and an intelligent network user unit (not shown).

As shown in FIG. 2, a message transfer unit (MTP), which is a function unit that reliably transfers No. 7 related messages transmitted and received between signal points of the No. 7 signal network, is connected to the signal traffic. Signaling message processing processor 20 which performs the function of transmission and signal message between user part ISUP, TUP and signal link, distribution to user part ISUP, TUP and signal link delivery, and reliable signal message delivery. A signal network that efficiently utilizes all the specifications included in the signal network, that is, signal links, signal link sets, and signal routes, and maintains consistency in the relationship among the corresponding signal network members and manages the shape of the signal network. It consists of a management processor 10.

In addition, the signal processing speed is improved by using a separate signal link for separating and transmitting only a control signal separately from a communication line (transmission path) for transmitting voice or data, and for the calling subscriber and the called subscriber. Various signal contents can be processed into a single signal unit, and the length of the corresponding signal unit can be set variably according to the amount of data.

On the other hand, a general No. 7 signal network that performs signal transmission and various communication services for control of a communication network, as shown in FIG. 3, is a signal point for transmitting, receiving, or transmitting a signal message generated by a user ( It consists of a Signaling Point (SP) and a Signaling Link (SL), which is a logical information transmission path connecting a corresponding signal point, that is, a local signal point and a relative signal point, and sends a signaling message to each corresponding signal point. Alternatively, there is a signaling signaling end point (SEP) and a signaling relay point (STP) configured as a pair to transfer a message from one signal link to another.

In addition, the signaling end point SEP includes an originating point (OP) that generates a signaling message and a destination point (DP) which is a destination of the signaling message.

The set of corresponding signal links SL is called a Signaling LinkSet (LS), and a path for delivering a message to a signaling point SP is called a signaling route (SR). The set of signal routes that are routing paths for is called Signaling RoutSet.

At this time, the No. 7 signal network is composed of the above-described signal network specifications, that is, the specification data for the signal point (SP), the signal link (SL), the signal link set (LS), the signal route (SR), The call message and the service request are performed by performing a routing function of the signal message generated by the OP) through the specific signal link SL of the signal link set LS directed to the destination point DP.

Each of the signal relay points STP is connected to two signal link sets LS for the stability and reliability of the No. 7 signal network. As shown in FIG. 4, the signal relay points STP1 In case of the signal relay point STP3, the signal link set LS13 connected to the signal relay point STP4 and the signal link set LS14 connected to the signal relay point STP2 are connected to the signal relay point STP2. It is connected to the signal link set LS23 connected to the signal link set LS23 connected to the signal relay point STP4.

As such, two or more sets of signal link sets (LS) are referred to as a combined link set in order to share the stability and reliability of the signal network and the signal traffic load.

Therefore, when a signal message is to be routed through a signal relay point for a specific signal point STP, signal traffic must be transmitted to each signal relay point to which two signal link sets LS are connected.

For example, when the signal message is to be routed from the signal relay point STP1 to the signal endpoint SEP-A in FIG. 4, the signal link set LS13 connected to the signal relay point STP3 at the signal relay point STP1. Signal traffic is distributed to the signal link set LS14 connected to the signal relay point STP4 and the distributed signal traffic is distributed to the signal link SL in the signal link set LS13 and LS14. When the signal relay point STP3 and the signal relay point STP4 are transmitted, the signal relay point STP3 and the signal relay point STP4 transmit the received signal message to the signal endpoint SEP-A.

As described above, the conventional signal traffic distributes the signal message to be routed to the signal link set forming the combined link set, and then redistributes the signal traffic distributed to each signal link set to the signal link in the signal link set to the next signal relay point. When a signal link in one signal link set fails, the signal traffic does not switch to a signal link in the other signal link set, and the signal traffic is switched only to an available signal link in the failed signal link set. There is a problem that congestion occurs because signal traffic is concentrated on the signal link of the link set.

In addition, when a load is divided into signal links in a combined link set by considering a region as a combined link set, signal points in the region have the same signal route, and thus, various routing configurations are impossible.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned general problems, and its object is to virtually treat a combined linkset as one signal linkset, thereby sharing the signal traffic between signal links in the combined linkset, thereby preventing the specific link within the combined linkset. Signal traffic is not concentrated on a signal link or there is no signal traffic on a specific signal link, and the signal traffic is evenly distributed to each signal link in the combined link set to provide load sharing of the signal traffic.

1 is a block diagram of a general No. 7 signal network.

FIG. 2 is a block diagram illustrating a function of a message transfer unit in the general No. 7 signal network shown in FIG.

Figure 3 is a schematic diagram showing the connection of each signal point and the signal link set in the general No. 7 signal network.

4 is a schematic configuration diagram of a signal link set and a combined link set in the general No. 7 signal network shown in FIG. 3;

5 is a flowchart illustrating the operation of performing a combined linkset definition in the No. 7 signal network according to the present invention.

6 is a flowchart illustrating an operation of performing signal traffic management in a combined link set in a No. 7 signal network according to the present invention;

7 is an operational flowchart of the combined link set specification management in the No. 7 signal network according to the present invention.

8 is a flowchart illustrating an operation of performing signal traffic routing management in a combined link set in a No. 7 signal network according to the present invention;

<Explanation of symbols for main parts of the drawings>

MTP: Message transfer unit SCCP: Signal connection control unit

SEP: Signal Endpoint STP: Signal Relay Point

SP: Signal Point SL: Signal Link

ISUP: Integrated Information Network User Part LS: Signal Link Set

A feature of the present invention for achieving the above object is, in the signal traffic load sharing method in the combined link set in the number seven signal network, the combined link constituting the individual signal link set constituting the combined link set as a virtual signal link set Defining three; Sharing the traffic load with the signal link in the virtual signal link set and transmitting it to the next signal point; Determining whether a non-available link exists due to a failure of the signal link in the virtual signal link set; Switching load sharing traffic to an available signal link if the unavailable signal link exists; Converting and returning the load sharing traffic to the entire signal link upon entering an available state due to failure recovery of the unusable signal link; If the message to be routed to the signal link is a message prohibiting routing to a specific signal point, performing a non-availability process for the corresponding route, and then routing the message through the available individual signal linksets; And if the message to be routed to the signal link is a transfer permission message, routing the message through an available combined link set.

In addition, the virtual signal linkset definition, the operator inputs a command for defining a virtual combined linkset; Determining whether two signal link sets input by an operator to define a combined link set are predefined in the system; If the two signal linksets defined by the operator are not defined, the corresponding information is notified to the operator. If the two signal linksets are defined, the signal linkset information constituting the combined linkset is informed. Storing; Determining whether a signal link exists in the signal link set constituting the combined link set; Notifying the operator of the corresponding information when the signal link does not exist, and storing information constituting the corresponding signal links if it is determined that the signal link exists; Determining whether there is an active signal link among the corresponding signal links; If the active signal link does not exist, inform the operator of the corresponding information, and if it is determined that the active signal link is present, manage traffic to relevant function processing means to perform traffic management for the corresponding signal links. It characterized in that it comprises a step of requiring.

When the two signal linksets constituting the combined linkset defined by the operator are defined in different types, the operator is informed of the information about the two signal linksets, and the two constituting the combined linkset defined by the operator. If the signal link set of the signal point of the different region is defined as the adjacent signal point characterized in that it informs the operator about the information.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the No. 7 signal network according to the present invention, since the configuration for explaining the signal traffic load sharing in the combined link set is the same as the conventional configuration described with reference to FIGS. 3 and 4, description thereof will be omitted.

Meanwhile, the operation of sharing the signal traffic load in the combined link set in the No. 7 signal network according to the present invention will be described with reference to FIGS. 5 to 8.

For example, the message sent from the signal point SEP1, which is the signal endpoint shown in FIG. 4, to the signal point SEP-A, which is the signal endpoint, is the next signal point, the signal relay point STP1, STP2. Is received at step S501, the processor in the signal relay point STP1 and STP2 analyzes the routing path information of the received message and processes the traffic for transmitting the received message to the next signal relay point STP3 STP4. It performs (S502).

At this time, the processor in the signal relay points STP1 and STP2 separates the individual signal link sets LS13 and LS14 that form the combined link set LS134 and LS234, which are logical information transmission paths between the next signal relay points STP3 and STP4. ) LS23 and LS24 are routed to the combined link set constituting the virtual signal link set (S503).

The virtual signal linkset configuration is performed according to the combined linkset definition command input by the operator. When the operator inputs a command to define the combined linkset, the signal linkset information and the signal link information table defined in the system are input. Based on the parameters entered by the operator, the information is stored and reported to the operator.

This will be described in more detail with reference to FIG. 6 as follows.

When the operator inputs a command to define a virtual combined linkset, the process of the corresponding signal relay point receives the input virtual combined linkset definition signal and parameters (S601) and then outputs the corresponding virtual combined linkset definition result. If it is determined that the DBMS to be stored is in an abnormal state by checking the state of the processor on which it is mounted, the operator is notified of the failure of the command, and then the execution of the function for defining the virtual combined link set is terminated. If it is determined that the normal state is maintained, it is determined whether two signal link sets constituting the virtual combined link set defined are already defined at the corresponding signal relay point (S602).

If it is determined that two signal linksets constituting the virtual combined linkset defined above do not exist, the related information is notified to the operator who inputs the virtual combined linkset definition command, and then the virtual combined linkset is defined. When the function ends (S608) and the operator has defined two signal linksets that define the virtual combined linkset in the corresponding signal relay point, the operator stores the combined linkset and the signal linkset information constituting the combined linkset ( S603).

Subsequently, it is determined whether a signal link exists in two signal link sets constituting the virtually defined combined link set (S604). If the signal link does not exist, the corresponding information is stored and notified to the operator side. If it is determined that the signal link exists in the two signal linksets, the information constituting the signal links belonging to the defined virtual combined linkset is stored (S605), and then the signals activated among the signal links belonging to the combined linkset. It is determined whether a link exists (S606).

If it is determined that the active signal link does not exist, the corresponding information is stored and notified to the operator. If the activated signal link is determined to exist, traffic management for activated signal links in the combined link set is determined. In order to perform the request for traffic management to the relevant function processing means (S607), and reports the result of performing the combined link set definition command to the operator (S608).

In the determination of S602, two signal linkset types constituting the combined linkset are defined to be different types, and in S604, signal points in regions where the signal links in the two signal linksets are different are adjacent signal points. In the case of notifying the operator of the input of the combined link set definition command, the operation for configuring the combined link set is terminated.

In addition, if the two signal linksets constituting the virtual combined linkset defined above are already configured with different combined linksets, the operator inputting a definition command to inform the operator that the combinational linkset cannot be configured is then combined. End the operation for link set configuration.

When the virtual combined link set is defined through the specification management of the combined link set as described above, the processor in the relay signal points STP1 and STP2 virtualizes the signal links of the individual signal link sets forming the defined virtual combined link set. After configuring the signal link belonging to the signal link set (S701), it is determined whether there is a signal link that is not available due to the occurrence of a failure among the configured signal links (S702).

If it is determined that there is a signal link that is not available due to a failure of the signal link, the load sharing is performed between the available signal links in the combined link set (S703), and then the next relay signal point (STP3) for the signal link belonging to the combined link set. STP4 switches the signal traffic (S704).

If it is determined that the failed signal link does not exist among the signal links belonging to the virtual signal link set, the entire signal link is available, and thus, the processor is provided with respect to all available signal links belonging to the combined link set. The load is shared to switch traffic to the next relay signaling point STP3 (STP4) (S708).

In the above-described signal link belonging to the virtual signal link set, when a faulty signal link exists and a signal link in a faulty state is recovered in a state in which traffic switching is performed by sharing a load among available signal links in the combined link set. Since the processor of the relay signal points STP1 and STP2 maintains the available state of all signal links belonging to the virtual signal link set, the load sharing is performed for the entire signal links in the combined link set, so that the next relay signal point STP3 STP4 switches the traffic to STP4 (S705-S707).

In addition, as shown in FIG. 8, when a message transmitted from a signal endpoint or a message broadcast from a signal relay point is received at a signal relay point that is an adjacent signal point, the processor of the signal relay point receives the received message. The analysis determines whether the message is a transmission prohibition message (S801-S803).

If it is determined that the transmission prohibition message is determined above, the processor of the relay signaling point performs a prohibition of prohibition of processing the signal route designated by the prohibition message and then includes a signal including another signal route that is not available. The traffic is transmitted by routing the received message to the individual signal link set available by acquiring the link set information (S804).

If the received message is not a transmission prohibition message, it is recognized that the message is a transmission permission message (S805). Since the processor of the corresponding signal relay point can be routed to a specific signal point through the combined link set, the available signal link set is available. Traffic transmission to a specific signal point is performed through load sharing routing to the signal link in step S806.

As described above, the present invention virtually regards a combined link set as one signal link set, thereby splitting signal traffic between signal links in the combined link set so that signal traffic is driven to a specific signal link in the combined link set or a specific signal link. There is no signal traffic in the network, and the signal traffic is evenly distributed across each signal link in the combined linkset, providing load sharing to provide stability and reliability for the signal traffic.

Claims (5)

A signal traffic load sharing method in a combined link set in a number seven signal network, Defining a combined link set constituting an individual signal link set constituting the combined link set into a virtual signal link set; Sharing the traffic load with the signal link in the virtual signal link set and transmitting it to the next signal point; Determining whether a non-available link exists due to a failure of the signal link in the virtual signal link set; Switching load sharing traffic to an available signal link if the unavailable signal link exists; Converting and returning the load sharing traffic to the entire signal link upon entering an available state due to failure recovery of the unusable signal link; If the message to be routed to the signal link is a message prohibiting routing to a specific signal point, performing a non-availability process for the corresponding route, and then routing the message through the available individual signal linksets; And routing the message through an available combined link set when the message to be routed to the signal link is a transmission permission message. delete delete delete The method according to claim 1, The virtual signal linkset definition comprises the steps of: an operator inputting a command to define a virtual combined linkset; Determining whether two signal link sets input by an operator to define a combined link set are predefined in the system; If the two signal linksets defined by the operator are not defined, the corresponding information is notified to the operator. If the two signal linksets are defined, the signal linkset information constituting the combined linkset is informed. Storing; Determining whether a signal link exists in the signal link set constituting the combined link set; Notifying the operator of the corresponding information when the signal link does not exist, and storing information constituting the corresponding signal links if it is determined that the signal link exists; Determining whether there is an active signal link among the corresponding signal links; If the active signal link does not exist, inform the operator of the corresponding information, and if it is determined that the active signal link is present, manage traffic to relevant function processing means to perform traffic management for the corresponding signal links. The signal traffic load sharing method in the combined link set in the number seven signal network comprising the step of requesting.