KR20000033346A - Method of outputting trouble message of switch link with loop-back test - Google Patents

Abstract

PURPOSE: A method is provided to output a trouble message to an operator when the loop-back result of a switch link is not proper to be used as a user call path. CONSTITUTION: A method of outputting a trouble message of a switch link includes the steps of: confirming the trouble of a switch link and calling a loop-back test to decide if the link is used as a service path; deciding whether the test result is abnormal; outputting a trouble message of the switch link if the result is abnormal; transmitting a test cell to a link to be tested as much as the test bandwidth required for observing the switch link if the loop-back test is called; and reporting the test cell after testing it.

Description

The fault message output control method of ATM switching link by using loopback test

The present invention relates to a method of controlling a failure message output of an ATM switching system switch link. In particular, the present invention relates to checking a failure state by performing a loopback test on a failed link and outputting a failure message to an operator when the system performance is affected. The present invention relates to a method of controlling a failure message output that can be performed.

Since the switch link is a resource that connects call paths between subscribers, the state of the switch link is always monitored by the monitoring control device. On the other hand, failures can occur repeatedly and recover on any switch link, and if all are notified to the operator as soon as they are found, in the worst case, a large number of failure messages are output on the same link, which can overload the system. Inefficiencies arise in operation.

Therefore, there is a need for a failure message output control method that checks a failure state for a failed link and outputs a failure message to an operator when it affects system performance.

The present invention has been made to solve the problems of the prior art as described above, and monitors the state of the switch link, if the switch controller detects and notifies the failure, performs a loopback test on the link, the loopback test results Its purpose is to provide an operator with a method to output a failure message when it is not suitable for use as a user call processing path because it is less than the performance of the corresponding path.

1 is a block diagram of an ATM switching system applied to the present invention,

2 is a configuration diagram of a switch network module constituting the ASNM or ISNM shown in FIG. 1,

3 is a flowchart illustrating a switch link state monitoring method according to an embodiment of the present invention;

4 is a flowchart illustrating a loopback test procedure illustrated in FIG. 3.

5 is a diagram illustrating a test cell loopback path for a switch link connected to an IM (matching board) according to an embodiment of the present invention.

6 is a diagram illustrating a test cell loopback path for a switch link connected to another switch according to an embodiment of the present invention.

7 illustrates a test cell loopback path for a switch link connected to a processor according to an embodiment of the present invention.

♠ Explanation of symbols on the main parts of the drawing ♠

101: user network interface (UNI)

102: network node interface (NNI)

103: subscriber switching subsystem 104: central switching subsystem

105: subscriber interface module (SIM)

107: Access Switching Network Module (ASNM)

108: call connection control processor (CCCP)

110: TIM (Trunk Interface Module)

112: Interconnection Switch Network Module (ISNM)

113: OMP (Operation and Maintenance Processor)

114: Cell Mux and Demux hardware Processor (CMDA)

115: test device

According to the present invention for achieving the object as described above, in the switch link failure message output control method located in the switch network module during the operation of the ATM switching system, when a switch link failure occurs, it checks the failure state and use as a service path A first step of invoking a loopback test to determine if it can be done; A second step of determining whether the loopback test result in the first step is abnormal; And a third step of outputting a switch link failure message when the loopback test result is abnormal, as a result of the determination of the second step.

In addition, in a computer-readable recording medium recording a program capable of executing a method for controlling a switch link failure message output located at a switch network module during an ATM switching system, when a switch link failure occurs, the failure status is checked and a service is provided. Invoking a loopback test to determine if it can be used as a path; A second step of generating one test cell after initializing the number of test cells to 0 when the loopback test is called in the first step; Transmitting a test cell generated in the second step to a link to be tested, and then increasing the number of test cells generated by one; A fourth step of analyzing the loopback test cell when the test cell transmitted to the test target link is loopback in the third step; A fifth step of determining whether the number of test cells analyzed in the fourth step matches the test band; A sixth step of notifying the analysis result of the fourth step if the number of test cells matches the test band as a result of the determination in the fifth step; As a result of the determination in the fifth step, if the number of test cells does not coincide with the test band, a computer-readable recording medium is provided which records a program capable of executing the seventh step to be repeated from the third step.

In the following, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail.

1 is a configuration diagram of an ATM switching system applied to the present invention, which will be described in detail as follows.

The ATM switching system is composed of a plurality of Atm Local Switching Subsystem (ALS) 103 and Atm Central Switching Subsystem (ACS) 104.

The subscriber switching subsystem (103) includes an access switching network module (ASNM) 107, which is a self routing switch module, a call connection control processor (CCCP) for user call processing and maintenance. System, 108), Subscriber Interface Module (SIM) 105 for subscriber matching, Trunk Interface Module (TIM) 110 for relay line matching, and ATM cells transmitted from the switch link to the Virtual Path Identifier (VPI). According to the switch to generate a test cell capable of testing the state of the link and the Cell Mux and Demux hardware Assembly (CMDA) 114 and the link to the processor or test device, and sequentially transmits the cells transmitted from the processor or test device to the switch The test device 115 transmits a cell to a link, receives a test cell looped back from a switch link, analyzes the result, and notifies the processor of the result. It is made.

The subscriber switching subsystem 103 operates as a concentrating device having a concentrating ratio of n: m, where n is the number of user-side links 106 and m is the number of switch-side links 109, and the central switching subsystem 104 is It acts as a distribution device for a large capacity system that performs the interconnection function between the subscriber switching subsystems (103). This will be described in detail as follows.

When a call request occurs from a subscriber through a User Network Interface (UNI) 101 and a Network Node Interface (NNI) 102, the subscriber switching subsystem 103 detects this and performs a call service. And translating the called subscriber switching subsystem through the called subscriber number under the supervision of the calling subscriber switching subsystem, and requesting the number translation to the called subscriber switching subsystem.

The terminating subscriber exchange subsystem selects an optimal route at the same time as number translation and notifies the originating subscriber exchange subsystem, and the originating subscriber exchange subsystem establishes a call path. The originating subscriber switching subsystem counts the cells delivered during the call, and sends the billing data to the central switching subsystem with the user requested service after the call is completed, and the originating subscriber switching subsystem restores the call data to the dormant state.

The central switching subsystem 104 is a pure interconnector with no call processing for exchanging information between the subscriber switching subsystems and, unlike the subscriber switching subsystem, does not have a call processing control unit.

The Interconnection Switch Network Module (ISNM) 112, which is a switch network module of the central switching subsystem, is a magnetic routing switch and may use the same switch element as the subscriber subsystem. The central exchange subsystem has an Operation and Maintenance Processor (OMP) 113 for system-wide operation and maintenance, as well as system-wide maintenance, testing, measurement, and statistical functions, as well as mass storage device control management and various inputs and outputs to and from the operator. Perform the door control function.

The CMDA 114 transmits the ATM cells coming from the switch link to the processor or test device according to the virtual path identifier (VPI), and sequentially transmits the cells transmitted from the processor or test device to the switch. The test apparatus 115 generates a test cell capable of testing the state of the link, transmits the cell to the switch link, receives and analyzes the test cell looped back from the switch link, and notifies the processor of the result.

FIG. 2 is a configuration diagram of a switch network module constituting the ASNM 107 or the ISNM 112 shown in FIG. 1, which includes two pairs of Switch Memory and Link board Assembly (SMLA) boards and a pair of Switch Link and SLCA. Controller board Assembly) It is composed of boards.

The SLCA board controls the Switch Network Module (SNM) and manages its state to interact with CCCP or OMP, the upper processor of the Switch Network Module. The software residing on the SLCA board receives the request from CCCP or OMP, the upper processor, runs the SMLA firmware to control the switch network module, and receives the status information of the switch network module from the SMLA firmware and transfers it to the upper processor.

In the present embodiment, two SMx boards are mounted in cascaded connections with two 16x16 unit switch blocks. Therefore, it is connected to another subsystem through 16 external links, and another SMLA board in the same subsystem through 8 internal links. SMLA is dual active type and is operated as a pair, and two pairs of SMLA boards are used to configure 32x32 switch.

3 is a flowchart illustrating a switch link state monitoring method according to an embodiment of the present invention.

First, link state monitoring is started, and in step S301, it is determined whether a switch link failure has occurred.

As a result of the determination, if a switch link failure does not occur, the process is repeated from step S301. If a switch link failure occurs, the loopback test is called in step S302 to check the failure state and determine whether it can be used as a service path. In step S303, it is determined whether the loopback test result called is abnormal.

If the loopback test result is abnormal in the determination result in step S303, the switch link failure message is output to the operator in step S304, and then repeated from step S301. If the loopback test result is normal, repeat from step S301. Perform.

4 is a flowchart illustrating the loopback test process illustrated in FIG. 3. The loopback test generates one test cell and generates and transmits a test bandwidth required by the switch link state monitoring function. By using one cell, loopback test can be performed at any time because it does not affect user call service during system operation.

This will be described in detail as follows.

First, in step S401, the number of test cells is initialized to zero, one test cell is generated in step S402, and then in step S403, the test cells are transmitted to the test target link.

Next, in step S404, the number of test cells generated is increased by one, and in step S405, the test cells are analyzed. In step S406, it is determined whether the number of test cells generated is equal to the test band.

As a result of the determination in step S406, if the number of generated test cells is equal to the test band, in step S407, the loopback test is notified after notifying the loopback test result, and if the number of generated test cells is different from the test band, from step S402 Repeat it.

5 is a diagram illustrating a test cell loopback path for a switch link connected to an IM (matching board) according to an embodiment of the present invention.

If a switch link connected to the IM fails, the link state monitoring function in the CCCP requires a loopback test to the test device (501). The test apparatus generates a test cell having a cell header that can be looped back in the IM as much as a bandwidth required by a link state monitoring function, transmits it to a switch through a CMDA (502), and passes through the switch. The cell sent to the IM (503) is looped back (504) and back to the test apparatus (505).

The test apparatus waits for a predetermined time for the transmitted test cell, analyzes the received test cell, and notifies the link state monitoring function in the CCCP of the loopback test result (506).

6 is a diagram illustrating a test cell loopback path for a switch link connected to another switch according to an embodiment of the present invention.

If a switch link connected to a switch in the ISNM fails, the link state monitoring function in the CCCP requires a loopback test to the test device (601). The test apparatus generates a test cell having a cell header that can be looped back in the ISNM as much as the bandwidth required by the link state monitoring function, transmits it to the switch through the CMDA (602), and passes through the switch (603) to the ISNM. The cell loops back 604, passes back the switch in the ASNM 605, and returns to the test apparatus 606.

The test apparatus waits for a predetermined time for the transmitted test cell, analyzes the received test cell, and notifies the link state monitoring function in the CCCP to a link back monitoring result (607).

7 is a diagram illustrating a test cell loopback path for a switch link connected to a processor according to an embodiment of the present invention.

If the switch link to the processor fails, the link state monitoring function in the CCCP requires a loopback test to the test device (701). The test apparatus generates a test cell having a cell header that can be looped back in the ASNM as much as the bandwidth required by the link state monitoring function, transmits it to the switch through the CMDA (702), and loops back from the switch to the test apparatus (703). .

The test apparatus waits for a predetermined time for the transmitted test cell, analyzes the received test cell, and notifies the link status monitoring function in CCCP to the link back monitoring result (704).

As described above, the present invention is recorded on a computer-readable recording medium and processed by a computer.

As described in detail above, the present invention monitors the state of a switch link of an ATM switching system, and when a switch controller detects and notifies a failure, performs a loopback test on the link, and the loopback test result does not meet the performance of the corresponding path. When it is inappropriate to be used as a user call processing path, it outputs a fault message to the operator, thereby preventing unnecessary fault message output, preventing the system load caused by the message output, and making it reliable through loopback test. .

The technical spirit of the present invention has been described above with reference to the accompanying drawings. However, the present invention has been described by way of example only, and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (4)

A method for controlling a switch link failure message output located in a switch network module during an ATM switching system, A first step of, if a switch link failure occurs, calling a loopback test to determine the failure status and determine whether it can be used as a service path; A second step of determining whether the loopback test result in the first step is abnormal; And a third step of outputting a switch link failure message if the loopback test result is abnormal as a result of the determination in the second step. The method of claim 1, The first step is, A fourth step of, when the loopback test is called, generating a test cell with a test bandwidth required by the switch link state monitoring function and transmitting the test cell to the test target link; And a fifth step of analyzing and notifying the test cell when the test cell transmitted to the test target link is looped back in the fourth step. The method of claim 1, The first step is, A fourth step of, if the loopback test is called, initializing the number of test cells to zero and generating one test cell; A fifth step of increasing the number of generated test cells by one after transmitting the test cells generated in the fourth step to a test target link; A sixth step of analyzing the looped-back test cell when the test cell transmitted to the test target link is looped back in the fifth step; A seventh step of determining whether the number of test cells analyzed in the sixth step matches the test band; An eighth step of notifying the analysis result of the sixth step if the number of test cells matches the test band as a result of the determination in the seventh step; And a ninth step of repeating the operation from the fifth step if the number of test cells does not match the test band as a result of the determination in the seventh step. A computer-readable recording medium having recorded thereon a program capable of executing a method for controlling a switch link failure message output located in a switch network module during an ATM switching system, comprising: A first step of, if a switch link failure occurs, calling a loopback test to determine the failure status and determine whether it can be used as a service path; A second step of generating one test cell after initializing the number of test cells to 0 when the loopback test is called in the first step; Transmitting a test cell generated in the second step to a link to be tested, and then increasing the number of test cells generated by one; A fourth step of analyzing the loopback test cell when the test cell transmitted to the test target link is loopback in the third step; A fifth step of determining whether the number of test cells analyzed in the fourth step matches the test band; A sixth step of notifying the analysis result of the fourth step if the number of test cells matches the test band as a result of the determination in the fifth step; And if the number of test cells does not coincide with the test band as a result of the determination in the fifth step, a computer-readable recording medium having recorded thereon a program capable of executing the seventh step of repeating the third step.