KR100325390B1 - Message Trnsfer Part Restart Method In No.7 Signaling Network - Google Patents

Abstract

The present invention resets signal network-related routing data of a corresponding signal network management processor while performing a signal message routing service at a signal message processing processor when a signal network management processor fails and recovers a message transmission load of a predetermined signal point in No. 7 signal network. The present invention relates to a method for restarting a message transfer unit in No. 7 signaling network.

Conventionally, when a signaling network management processor fails, the signaling point itself is excluded from service, causing a failure of adjacent signaling points due to the network management load, which causes a failure of the entire signaling network. There was this.

The present invention separates the signal network management processor and the signal message processing processor during the failure and recovery of the message network management processor at the predetermined signal point in the No.7 signal network, thereby continuing the signaling message routing service in the corresponding signal message processing processor. By doing this, it is possible to prevent the network failure due to the failure and recovery of the signal network management processor.

In addition, the present invention responds to the signal link test of the adjacent signal point in the signal message processing processor, and performs the signal link test function and the restart request request for the adjacent signal point at the recovery of the signal network management processor, thereby performing No. 7 signal. Routing data related to signal links and signal points in the network can be quickly reset.

Description

Message Trnsfer Part Restart Method In No.7 Signaling Network}

The present invention relates to a method for restarting a message delivery unit in No. 7 signaling network, and more particularly, while performing a signal message routing service in a signal message processing processor during a failure and recovery of a signal network management processor of a message delivery portion of a predetermined signal point. The present invention relates to a method for restarting a message transfer unit in a No.7 signal network that enables resetting of signal network related routing data of a signal network management processor.

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 for providing call connection and various communication services or operating and managing communication networks between subscribers. As a signaling method for transmitting a signal, the No. 7 signal network structure is a network service for sharing transmission control, error correction, and security measures for a signal network, as shown in FIG. ITP (ISDN User), which is an MTP (Message Transfer Part), a Signaling Connection Control Part (SCCP), and a user part that is individually designed according to application fields such as telephone exchange and data exchange. Part), Transaction Capability (TCAP) and Telephone User Part (TUP). Intelligent network user unit (not shown).

Here, the corresponding message transfer unit (MTP) performs a function of transmitting a signal message transmitted and received between the signal points of the No. 7 signal network, as shown in the accompanying Figure 2, the signal traffic transmission and the user portion distribution A signal message processing processor 20 that performs a function, and all the specifications included in the signal network, that is, signal links, signal link sets, signal points, and signal routes, can be efficiently used for reliable signal message transmission. It consists of a signal network management processor 10 which maintains the consistency between the specifications and manages the signal network shape.

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

On the other hand, the conventional No. 7 signal network as shown in the accompanying drawings, Figure 3, connecting a signal point (SP; Signaling Point) for sending, receiving, or transmitting a signal message generated by the user, and the connection between the signal point Signaling link (SL), which is a logical information transmission path, which has a signaling relay point (STP) for transmitting a message for sending or receiving a signaling message. An endpoint includes an originating point (OP) that generates a signaling message and a destination point (DP) that is a destination of the signaling message.

The set of corresponding signal links is called a signaling link set (LS), and a path for delivering a message to a signaling point is called a signaling route (SR), which is a routing path for one signal destination point. The set of signal routes is called a signal route set. The No. 7 signal network is composed of the above-described signal network specifications, that is, the data points for the signal point, the signal link, the signal link set, and the signal route, and are generated by the origin point. The signaling message is delivered through a specific signal link of a signal link set destined for a called point (called routing) to perform a call connection and a service request.

In the conventional No. 7 signal network, the message transfer unit structure of each signal point is shown in FIG. 4 as shown in FIG. 4. The network management processor 10, the IPC (Inter-Processor Communication) processor 15, and a plurality of It comprises a signal message processing processor 20, if a failure occurs in the signal network management processor 10 that performs the signal network management function to the corresponding signal network change (signal link failure, signal point limit / prohibition, etc.) Since the routing data could not be updated, the corresponding signaling point was excluded from the signaling network service.

However, in the large-scale No. 7 signal network, the failure of the signal network management processor 10 as described above has a problem that can cause the failure of adjacent signal points and spread to the entire signal network failure. In particular, when the signaling network management processor 10 recovers from a failure within a short time, even though there is almost no change in the signaling network, excluding the signaling point itself from the signaling network service rather puts a load on the signaling network. There was a problem causing disability.

The present invention has been made in view of the above-described problems, and an object thereof is to provide a corresponding signal network management processor and a signal message processing processor in case of failure and recovery of a message delivery controller of a message transmission load of a predetermined signal point in No. 7 signal network. By separating, the signaling message processing processor can perform a continuous signaling message routing service, thereby preventing a network failure due to the failure and recovery of the signaling network management processor.

Another object of the present invention is to respond to a signal link test of an adjacent signal point in a signal message processing processor, and perform a signal link test function and a restart request request for an adjacent signal point when the signal network management processor recovers. .7 to enable rapid resetting of routing data for signal links and signal points in a signal network.

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

2 is a block diagram illustrating a function of a message transfer unit in FIG. 1;

3 is a schematic configuration diagram of a general No. 7 signal network.

4 is a conceptual diagram of a message transfer unit of each signal point in the conventional No. 7 signal network.

5 is a conceptual diagram of the message transfer unit operation of each signal point in the No. 7 signal network according to the present invention.

6 is a flowchart illustrating a processor separation and signaling message routing service operation when a message transfer unit fails in a No. 7 signaling network according to the present invention.

7 is a flowchart illustrating a signal link test operation when recovering a message transfer unit in No. 7 signal network according to the present invention.

8 is a flowchart illustrating a request for restart start operation for an adjacent signal point in the No. 7 signal network according to the present invention.

9 is an operation flowchart for performing step 1 when the local signal point resumes in the No. 7 signal network according to the present invention;

10 is a flowchart illustrating an operation for performing two steps when the local signal point restarts in the No. 7 signal network according to the present invention.

Explanation of symbols on the main parts of the drawings

50: signal network management processor 55: IPC processing unit

60: signal message processing processor

A feature of the present invention for achieving the above object is, in the signal network management processor failure of the signal point in the No.7 signal network and the method of restarting the message transfer unit during recovery, the failure occurs in the signal network management processor Performing a signal message routing service by separating the signal network management processor from the signal message processing processor; Resetting the signal link and signal point related routing data by performing a signal link test and a restart request for an adjacent signal point when the signal network management processor recovers; And resuming the message transfer unit by reconfiguring routing data for the signal link set and the signal route by resuming the local signal point.

The process of separating the signal network management processor and the signal message processing processor to perform a signal message routing service may include switching to a signal network management processor failure mode when the signal message processing processor recognizes a failure of the signal network management processor. Steps; Performing routing of signal messages and transmitting them to adjacent signal points; Transmitting a response message to a signal link test message from the neighbor signal point to the neighbor signal point to process a signal link test function; Confirming whether the signal network management processor recovers from a failure; When the recovery from the failure is characterized in that it comprises the step of switching to the normal mode.

The resetting of the signal link and the signal point related routing data upon recovery of the signal network management processor may include: setting all signal links to a level 2 service state; Sending a signal link test message to an adjacent signal point; Confirming whether a signal link test response message is received from the adjacent signal point; And setting a specification data state for the signal link according to whether the signal link test response message is received.

Further, the process of resetting the signal link and the signal point-related routing data when the signal network management processor recovers may include: setting a specification data state for the signal link and transmitting a permission message to the adjacent signal point when signal traffic resumes; ; And receiving routing prohibition / restriction message from the adjacent signaling point to set signaling point related routing data.

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, the structure of the message transfer unit of the signal point is shown in FIG. 5 as shown in FIG. 5. The signal network management processor 50, the IPC processing unit 55, and the plurality of signal message processing processors 60 are shown in FIG. 5. When a failure occurs in the signal network management processor 50, each signal message processing processor 60 performs a test for each signal link while performing a routing service for the signal message, and performs the corresponding signal. When the network management processor 50 recovers from a failure, the network management processor 50 restarts the corresponding message transfer unit by performing a signal link management function, a restart request request for an adjacent signaling point, and a restart and monitoring function of a local signal point. .

The operation of restarting the message transfer unit at the signal point of No. 7 signal network according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, when a failure occurs in the signal network management processor 50 of the message transfer unit, the signal network management processor 50 and the signal message processing processor 60 are separated, and then the signal message processing processor 60 is continuously. While performing a signal message routing service, a test is performed for each signal link. As shown in the operation flowchart illustrated in FIG. 6, the signal message processing processor 60 detects a failure of the corresponding signal network management processor 50. Upon recognition (step S1), the signal message processing processor 60 switches to the signal network management processor failure mode (step S2), whereby the signal network management processor 50 and the signal message processing processor 60 are separated.

Then, when the predetermined signal message is received from the adjacent signal point through the signal link (step S3), the corresponding signal message processing processor 60 performs routing on the received signal message (step S4), and the corresponding adjacent signal. The data is transmitted to the point (step S5). At this time, the corresponding signal message processing processor 60 transmits the signal message to the other signal message processing processor 60 through the IPC processing unit 55 when the adjacent signal point for transmitting the received signal message is not the adjacent signal point to be processed. The signal is transmitted to the corresponding adjacent signal point.

On the other hand, the signal message processing processor 60 performs the signal message routing as described above, and simultaneously receives the signal link test message from the adjacent signal point through the signal link (step S6), the received signal link test message is transmitted. By sending the response message to the corresponding signal point (step S7), the signal link test function is processed so that the test of the signal signal can be performed at the signal point.

Then, the signal message processing processor 60 checks whether the signal network management processor 50 recovers from the failure (step S8), and if the signal network management processor 50 does not recover from the failure, the signal message is received and signaled. When the signal network management processor 50 recovers from the failure, the signal network management processor 50 returns to the operation of processing the reception of the link test message, and then switches from the signal network management processor failure mode to the normal mode (step S9). Only the original signal message processing function is performed.

On the other hand, when the signal network management processor 50 recovers from a failure, the signal network management processor 50 performs a signal link test function and a restart start request function for neighboring signal points and a local station to recover the signal network related routing data. The signal point restart and monitoring function is performed to perform the function of restarting the message transfer unit. First, the signal link test operation will be described with reference to FIG. 7.

Since the signal network management processor 50 has continuously performed a response to the signal link test of the adjacent signal point by the signal message processing processor 60, after setting all the signal links to the level 2 service state (step) S11), the IPC processing unit 55 and each signal message processing processor for signal link test for resetting the specification data state for each signal link connected to the corresponding signal message processing processor 60, that is, the signal link associated with the corresponding signal point. Through 60), the signal link test message is transmitted to the adjacent signal point (step S12).

Then, it is confirmed whether or not the signal link test response message is normally received from each adjacent signal point which has transmitted the corresponding signal link test message (step S13), so that the signal link test response message is active and available for the signal link normally received. The specification data state is set (step S14), and the specification data state is set to an inactive and unavailable state for the signal link for which the signal link test response message is not normally received (step S15).

Here, the specification data state means a state such as availability or non-availability of the specification data for constituting the routing data.

Secondly, a restart start request operation for a corresponding neighboring signal point will be described with reference to FIG. 8 as follows.

The signal network management processor 50 resets the specification data state for the signal link, and then restarts the signal traffic through the IPC processing unit 55 and each signal message processing processor 60 to reset the signaling point related routing data. The allow message is transmitted to the adjacent signal point (step S21).

Then, as each neighboring signaling point receives an allow message to resume unexpected signal traffic, the neighboring signaling point resumption procedure is performed through the signaling link to prohibit / restriction messages for unreachable or restricted access signaling points. Will be sent.

Accordingly, the signal network management processor 50 receives the prohibition / restriction message from adjacent signal points through each signal message processing processor 60 and the IPC processing unit 55 to reset the signal point related routing data (step). S22).

When the signal for restarting the signal traffic is received from the neighboring signal point (step S23), the restart operation for the neighboring signal point is terminated.

Finally, the signal network management processor 50 resets the specification data state for the signal link, and then performs the restart request request for the adjacent signal points as described above to reset the signal point related routing data. In order to reset the routing data for the signal link set and signal route defined in the standard, the local station signal point restart and monitoring operation is performed. When the point resumes, it is performed in two steps.

First, with reference to the operation flowchart shown in FIG.

The signal network management processor 50 drives the signal link activation monitoring timer and the local station signal point restart timer (step S31), and after transitioning to the first stage when the local station signal point resumes (step S32), the signal link test operation is performed. If the signal link is confirmed to be active and available (step S33), the signal link set is also available, so that all signal routes using the available signal link set are set to the available state (step S34). ), Check that the routing data reset for all signal linksets and signal routes has ended, i.e., that step 1 when local signal point resumption has ended (step S35), so that routing data resets for all signal linksets and signal routes have been completed. If it is not terminated, it returns to step S33 to perform a repeating operation, thereby resetting routing data for all signal linksets and signal routes.

Subsequently, when the routing data reset for all the corresponding signal linksets and signal routes is terminated, the corresponding signal network management processor 50 stops driving the signal link activation watchdog timer upon resumption (step S36), and resumes the local signal point. The process proceeds to two stages of time (step S37).

On the other hand, the signal network management processor 50 receives the transfer prohibition / restriction message from the neighboring signal point by the above-described restart request operation for the neighboring signal point after transitioning to the first step of restarting the local signal point in step S32. (Step S38), since the signal link is inactive and unusable, after setting the specification data state to the signal link set and all signal routes using the signal link set as unavailable (step S39), step S35 By performing the operation of repetition, the routing data for all signal linksets and signal routes are reset.

Then, the signal network management processor 50 transitions to the first step of restarting the local signal point in step S32, and then, upon receiving the above-mentioned restart request request for the neighboring signal point, generates the signal traffic restart permission message from the adjacent signal point. When the signal link is sufficiently received (step S40) and the signal link is sufficiently activated (step S41), the operation of step S36 for stopping the signal link activation monitoring timer at the time of resumption is completed in order to complete the step 1 when the local station signal point resumes.

In addition, the signal network management processor 50 repeatedly performs the above-described operations, and when the signal link activation monitoring timer is restarted (step S42), the signal network management processor 50 transitions to step 2 when the local signal point is restarted in step S37.

Next, with reference to the accompanying drawings, the second step of restarting the corresponding country signal point is described as follows.

When the signal network management processor 50 transitions to the second stage at the time of restarting the local station signal point (step S51), the signal link test operation described above is interrupted (step S52), and then the state of the signal route with respect to the called party signal point. Accordingly, the signal point is updated to an unreachable state or an access restriction state (step S53), and the IPC processing unit 55 and each signal message processing processor 60 are made from the destination point according to the updated signal point state. The transmission prohibition / limiting message is transmitted to the adjacent signal point via (step S54).

After stopping the timer driving when the local station signal point restarts (step S55), the signal for allowing signal traffic restart resumes to the adjacent signal point is transmitted through the IPC processing unit 55 and each signal message processing processor 60 (step S55). S56), the watchdog timer is driven after the restart (step S57), and the state transitions to the watched state after the restart of the own station signal point (step S58).

On the other hand, when the signal network management processor 50 transitions to the step 2 at the time of restarting its own signal point in step S51, and receives a delivery message (prohibition of transmission, transfer allowance, transfer restriction) from an adjacent signal point (step S59). Then, the corresponding transfer procedure is performed (step S60), and the above-described operation is repeatedly performed.

Further, the signal network management processor 50 repeatedly performs the above-described operations, and when the local signal point restart timer expires (step S61), transmits a permission message for restarting signal traffic to an adjacent signal point (step S56). After restarting, the monitoring timer is driven (step S57), and the state transitions to the monitoring state after restarting the own station signal point (step S58).

Subsequently, when the signaling network management processor 50 transitions to the monitoring state after restarting its own signaling point, that is, the monitoring state is restarted after restarting the message delivery unit, when the monitoring timer is driven after the restart, the signal traffic restarts from the adjacent signaling point. If the allow message is received, it is ignored. If the watchdog timer expires after the restart, the watchdog operation is terminated after the restart.

In addition, the embodiments according to the present invention are not limited to the above-described embodiments, and various alternatives, modifications, and changes can be made within the scope apparent to those skilled in the art.

As described above, the present invention separates the signal network management processor and the signal message processing processor at the time of failure or recovery of the signal network management processor of the message transfer load at a predetermined signal point in No. 7 signal network, and continues the signal message processing processor. By performing the signaling message routing service, it is possible to prevent the network failure due to the failure and recovery of the signaling network management processor.

In addition, the present invention responds to the signal link test of the adjacent signal point in the signal message processing processor, and performs the signal link test function and the restart request request for the adjacent signal point at the recovery of the signal network management processor, thereby performing No. 7 signal. Routing data related to signal links and signal points in the network can be quickly reset.

Claims (4)

A method for restarting a message transfer unit in a signal network management processor failure and recovery of a signal point in a signal network No.7, Performing a signal message routing service by separating the signal network management processor and the signal message processing processor when a failure occurs in the signal network management processor; Resetting the signal link and signal point related routing data by performing a signal link test and a restart request for an adjacent signal point when the signal network management processor recovers; And restarting the message transfer unit by reconfiguring routing data for the signal link set and the signal route by restarting the local signal point. The method of claim 1, The process of separating the signal network management processor from the signal message processing processor and performing a signal message routing service may include switching to a signal network management processor failure mode when the signal message processing processor recognizes a failure of the signal network management processor. ; Performing routing of signal messages and transmitting them to adjacent signal points; Transmitting a response message to a signal link test message from the neighbor signal point to the neighbor signal point to process a signal link test function; Confirming whether the signal network management processor recovers from a failure; Reverting to the normal mode when recovering from the failure. Number. The method of restarting the message delivery unit in the seven signal network. The method of claim 1, The resetting of the signal link and signal point related routing data when the signal network management processor is restored may include: setting all signal links to a level 2 service state; Sending a signal link test message to an adjacent signal point; Confirming whether a signal link test response message is received from the adjacent signal point; And setting a specification data state for the signal link according to whether the signal link test response message has been received. The method of claim 1, The resetting of the signal link and signal point related routing data upon recovery of the signal network management processor may include: setting a specification data state for the signal link and transmitting a permission message to resume the signal traffic to an adjacent signal point; And receiving routing prohibition / restriction message from the adjacent signaling point and setting routing point related routing data.