KR100464149B1 - Method for fail information assignment in switching system - Google Patents

Abstract

The present invention relates to a method for assigning fault information of an exchange that allows assigning fault information according to a shape change (addition / deletion) of the exchange, thereby enabling a fault handling according to the shape change without interruption of service and inconvenience of an operator.

Conventionally, to modify the fault of the added / deleted shape through the Embedded Data Manipulation Language (EDML), or to configure and load a new fault information DBMS to the processor, EDML has to be performed as many faults of the added / deleted shape. There is a problem, and when loading a newly configured DBMS to the processor, there is a problem that the service must be stopped.

The present invention allocates fault information based on the shape information collected by the configuration management target hardware at the time of system setting, and automatically or automatically corrects the fault information on the shape information changed according to the shape change (addition / deletion) during service operation. By assigning them according to the operator's requirements, it is possible to provide fault management for the new configuration without interrupting service, thereby providing continuous and stable fault management and status management.

Description

Method for fail information assignment in switching system

The present invention relates to a method for assigning fault information of an exchange, and in particular, assigns fault information according to the shape change (addition / deletion) of the exchange, so that fault handling according to the shape change can be performed without interruption of service and inconvenience of the operator. It relates to a failure information allocation method of the exchange.

In general, an exchange consists of units, which are physical basic units that perform specific functions, and are based on failure units, which are composed of several hardware blocks to perform specific functions. The failure to output for the blocks will be selected and assigned.

Fault information consists of information needed for fault output such as fault level, fault code, physical location, etc. According to the shape information of the system, the unit performs shape control such as fault assignment / unassignment to DBMS (Database Management System). .

As described above, the failure information DBMS assigned according to the system configuration information is loaded into the processor (CPU), and when a failure occurs, the failure information DBMS is referred to by the failure processing related block and outputs a failure based on this.

That is, as shown in FIG. 1, when the hardware block is added / deleted and the processor detects the shape change of the hardware block (S10), the hardware block in which the shape change is detected in step S10 is searched for by searching the shape management DBMS. It is judged whether or not it is implemented (S12).

As a result of the determination in step S12, if the hardware block in which the shape change is detected in step S10 is unmounted, the failure occurring in the hardware block in which the shape change is detected in step S10 is ignored (S14). When the hardware block in which the shape change is detected in one step S10 is implemented, after the failure information is extracted from the failure information DBMS (S16), a failure is generated or released according to the shape change detected in the above step S10 (S18). ). That is, when the shape change detected in step S10 is a shape change due to deletion of a hardware block, a failure is generated for the corresponding hardware block, and the output is generated, and the shape change detected in step S10 is a shape due to the addition of a hardware block. In the case of a change, the fault on the corresponding hardware block is released.

As described above, in the prior art, the fault information DBMS containing information required for fault output is configured according to the current system shape information. Once configured and loaded into the CPU, the system information cannot be changed in the middle. It is not possible to perform shape control for addition / deletion of.

In other words, regardless of hardware mounted / unmounted information, mounted / unmounted information is determined according to software configuration management DBMS, so if it is implemented in configuration management DBMS, even if the configuration is not implemented in hardware, However, if the configuration management DBMS is not mounted, even if the configuration is installed in hardware, it is not part of the configuration, so even if a failure occurs, the operator cannot be notified of the failure.

Therefore, in the related art, a fault of a shape added / deleted in the first method is modified through EDML (Embedded Data Manipulation Language), and a second fault information DBMS is configured and loaded into the processor in the second method.

However, the first method described above has a problem that EDML should be performed as many as the number of failures of the added / deleted shape, and the second method has a problem that the service should be stopped when the newly configured DBMS is loaded into the processor.

The present invention has been made to solve the above-mentioned problems, by assigning the failure information for the shape information changed according to the shape change (addition / deletion) during the service operation automatically or according to the operator's request, the new shape without interruption of the service The purpose of the present invention is to provide a method for assigning fault information of an exchange that enables fault handling to provide continuous and stable fault management and status.

1 is a view for explaining a failure information output method of a conventional exchange.

2 is a view showing a state transition of shape information and fault allocation information applied to the present invention.

3 is a flowchart for explaining a failure information allocation method of the exchange according to the present invention;

4 is a flowchart for explaining an initial process of FIG. 3.

5 is a flowchart for explaining a shape addition process of FIG. 3.

6 is a flowchart for explaining a shape deletion process of FIG. 3.

In order to achieve the above object, the fault information allocation method of the exchange of the present invention collects the shape information of the hardware blocks to be managed during configuration, and changes the shape information and the fault allocation information based on the collected shape information. Process of doing; When detecting a failure from the hardware block, changing the shape information of the hardware block according to whether the shape information of the hardware block is 'mounted'; When detecting mounting of a hardware block, changing shape information of the mounted hardware block, and outputting a status change message indicating a mounting state of the mounted hardware block to an operator; Changing failure allocation information of the mounted hardware block by receiving change of failure information from the operator; Changing failure allocation information of a hardware block to be deleted by receiving change of failure information from the operator; When detecting the deletion of the hardware block to be deleted includes changing the shape information of the deleted hardware block and outputting a status change message indicating the deleted state of the hardware block to the operator.

Here, in the process of changing the shape information of the hardware block according to whether the shape information of the hardware block is set to 'mounting', when the failure is detected from the hardware block, the shape information of the hardware block is 'mounted'. Determining whether it is made; When the shape information of the hardware block is 'mounted', determining whether the detected failure is related to occurrence of a failure; If the shape information of the hardware block is 'mounted', if the detected failure is related to a failure, the shape information of the hardware block is changed to 'unmounted', and if the detected failure is not related to a failure, Ignoring the detected failure; If the shape information of the hardware block is 'unmounted', determining whether the detected failure is related to a failure occurrence; If the shape information of the hardware block is 'unmounted', if the detected failure is about failure, the detected failure is ignored, and if the detected failure is not about failure, the shape information of the hardware block is It characterized in that it comprises a step of changing to 'mounting'.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the failure information allocation method of the exchange according to a preferred embodiment of the present invention.

First, in order to implement the fault information allocation method of the exchange according to the present invention, both hardware shape information and software fault allocation information should be known. As shown in Table 1, the hardware shape information and the software fault allocation information are 4; It consists of four state combinations.

Shape information (H / W) Disability Assignment Information (S / W) Explanation One Unmounted Unassigned H / W is not mounted and no fault is assigned. (Initial state before collecting shape information) 2 Unmounted Assignment The H / W is not mounted or assigned a fault (the fault status of the H / W). 3 Chief Unassigned An abnormal state in which the fault information is changed by the operator arbitrarily. 4 Chief Assignment H / W has been mounted and fault assigned (mounted / disarmed after collecting shape information).

As shown in Table 1, the hardware shape information and the software failure assignment information are composed of four state combinations, and the four states cause state transitions between each other, as shown in FIG.

As described above, the four states can change state in all five forms, as shown in FIG. 2, and Table 2 shows the types of the state variations that can appear in the present invention.

number transition Explanation One Initial shape attempt variation It means a state transition from unmounted / unassigned to unmounted / unassigned, which occurs when there is no change in shape after requesting shape information from the initial value. 2 Initial shape change variation This refers to a state transition from unmounted / unassigned to mounted / assigned, which occurs when a shape change (addition) is made after requesting shape information from an initial value. 3 Disturbance / Release Variation State transitions from unmounted / assigned to unmounted / assigned refer to the occurrence of a disorder, and state transitions from unmounted / assigned to mounted / assigned refer to the release of the disorder. 4 Shape change variation State transitions from unmounted / unassigned to unmounted / unassigned refer to the addition of hardware geometry, while state transitions from unmounted / unassigned to unmounted / unassigned refer to the removal of hardware geometry. Distinguish in terms of the output of the fault. 5 Operator demand variation This is a state change made by the operator prior to the change (addition / deletion) of the hardware configuration.

3 is a flowchart illustrating a method for assigning fault information of an exchange according to the present invention. The method for assigning fault information of an exchange according to the present invention is a state in which fault processing is possible by collecting shape information existing in a system at the time of system setting. For the initial process (S100) of assigning fault information to the user, the shape addition process (S200) of assigning fault information to the hardware shape added by the operator during service operation, and the hardware shape deleted by the operator during service operation. It includes a shape deletion process (S300) for deleting the failure information.

4 is a flowchart illustrating an initial process (S100) of FIG. 3. When a system is configured, a processor requests configuration information from configuration management target hardware blocks in which a CPU exists and collects configuration information from the hardware blocks. (S110).

Subsequently, based on the configuration information collected in step S110, information for configuration management / disability processing is configured. The hardware block mounted as a result of the configuration information checking collected in step S110 is 'unmounted'. The initialized hardware shape information is changed to 'mounted', and the failure assignment information initialized to 'unassigned' is changed to 'assigned' (S115 and S120).

On the other hand, for the hardware block that has received the shape information that is not mounted as a result of the shape information collected in the process S110 described above was not initialized to "unassigned" without changing the hardware shape information initialized to "unmounted" Failure assignment information is also not changed (S125).

Whether or not the hardware block is mounted in step S115 can be known from the shape information received according to the shape information request. The hardware block transmitting the shape information according to the shape information request is mounted and does not transmit the shape information. It can be determined that the hardware is not mounted.

As described above, when a failure is detected from predetermined hardware after configuring the information for configuration management / failure processing, it is determined whether the shape information of the hardware block in which the failure is detected is 'mounted' (S130 and S135).

As a result of the determination of step S135, when the shape information of the hardware block in which the failure is detected is 'mounting', it is determined whether the detected failure is related to failure by checking the failure detected in step S130 (S140). ).

As a result of the determination of step S140, if the failure detected in step S130 is related to the occurrence of a failure, the shape information of the detected hardware block is changed from 'mounted' to 'unmounted' (S145). When the failure detected in S130 is related to the release of the failure, not the occurrence of the failure, the failure detected in the above-described process S130 is ignored (S150).

On the other hand, if the shape information of the hardware block in which the failure is detected is 'unmounted' as a result of the determination of step S135, it is determined whether the detected failure is related to failure by checking the failure detected in step S130. (S155).

As a result of the determination in step S155, if the failure detected in step S130 is related to the occurrence of a failure, the failure detected in step S130 is ignored (S160), and the failure detected in step S130 is not a failure. If it is related to the failure release, the shape information of the hardware block in which the failure is detected is changed from 'unmounted' to 'mounted' (S165).

FIG. 5 is a flowchart illustrating the shape adding process S200 of FIG. 3, in which hardware shape information is 'unmounted' and failure allocation information is 'unassigned', that is, mounted in a system. When mounting on a hardware block that is not already detected is detected (S210), the shape information of the mounted hardware block is changed from 'unmounted' to 'mounting' (S220), and a shape is added to notify an operator that a new hardware block is mounted. A state change message is output (S230).

Subsequently, the failure information is controlled by the operator, and the failure assignment information of the hardware block newly installed in the process S210 is changed from 'unassigned' to 'assigned' (S240).

FIG. 6 is a flowchart for describing the shape deletion process S300 of FIG. 3. In order to delete (separate) a hardware block mounted in a system, an operator first has hardware shape information set to 'mount', and has a failure. The failure information of the hardware block for which the assignment information is 'assigned', that is, the hardware block to be deleted among the hardware blocks mounted in the system is changed from 'assigned' to 'unassigned' (S310).

As described above, after changing the fault assignment information of the hardware block to be controlled and deleted from the operator by changing the information from 'assigned' to 'unassigned', the fault assignment information is changed to 'unassigned'. When the deletion (hernia) is detected (S320), the shape information of the deleted hardware block is changed from 'mounted' to 'unmounted' (S330), and a shape deletion state change message is sent to inform the operator that the hardware block has been deleted. Output (S340).

As described above, when the hardware configuration is simply changed (added / deleted), only the status message is outputted so that it is irrelevant to the management of the status of failures and resources, and the failure is detected when the hardware is removed / mounted during operation. Print a message to reflect the status of failures and resources.

The failure information allocation method of the exchange of the present invention is not limited to the above-described embodiments, and can be modified in various ways within the scope of the technical idea of the present invention.

According to the fault information allocation method of the exchange of the present invention as described above, the fault information is allocated based on the shape information collected by the configuration management target hardware upon system setting, and the shape is changed (added / deleted) during service operation. By assigning the fault information on the changed configuration information according to the automatic or operator's request, it is possible to provide fault management for the new configuration without interruption of service and to provide continuous and stable fault management and status management. .

In addition, the shape management / failure processing can be provided only for the shape existing in hardware.

Claims (4)

Collecting shape information of the shape management target hardware blocks when the system is set, and changing shape information and fault allocation information based on the collected shape information; When detecting a failure from the hardware block, changing the shape information of the hardware block according to whether the shape information of the hardware block is 'mounted'; When detecting mounting of a hardware block, changing shape information of the mounted hardware block, and outputting a status change message indicating a mounting state of the mounted hardware block to an operator; Changing failure allocation information of the mounted hardware block by receiving change of failure information from the operator; Changing failure allocation information of a hardware block to be deleted by receiving change of failure information from the operator; Detecting the deletion of the hardware block to be deleted, changing the shape information of the deleted hardware block and outputting a status change message indicating a deletion state of the hardware block to an operator; How to assign. The method of claim 1, The process of changing the shape information of the hardware block according to whether the shape information of the hardware block is set to 'mounting', Determining whether shape information of the hardware block is 'mounted' when detecting a failure from the hardware block; When the shape information of the hardware block is 'mounted', determining whether the detected failure is related to occurrence of a failure; If the shape information of the hardware block is 'mounted', if the detected failure is related to a failure, the shape information of the hardware block is changed to 'unmounted', and if the detected failure is not related to a failure, Ignoring the detected failure; If the shape information of the hardware block is 'unmounted', determining whether the detected failure is related to a failure occurrence; If the shape information of the hardware block is 'unmounted', if the detected failure is about failure, the detected failure is ignored, and if the detected failure is not about failure, the shape information of the hardware block is And changing the information to 'mounting'. delete delete