KR100388081B1 - Test method for standby time switch path of exchange - Google Patents

Abstract

The present invention relates to a standby time switch path test method of a switch for testing whether the standby path of a duplicated time switch is normal during the on-line service of the exchange under the control of an upper control unit. When the time switch unit in the state is switched to standby state, regardless of whether or not the time switch unit is currently in standby state, the redundant switch is performed and if the time switch unit in the active state is bad as the service continues, There was a problem that caused serious disruption of service.

Accordingly, the present invention provides a standby path test function between a time switch in a standby state and a lower device without an additional subhighway matching path in a redundant time switch of the exchange, thereby improving the system diagnostic function of the exchange.

Description

How to test the standby time switch path of the exchange

The present invention relates to a standby time switch path test of an exchange, and more particularly, to a standby time switch path test method of an exchange configured to test whether a standby path of a duplicated time switch is normal during an online service under the control of an upper controller. .

In general, the interface device between the time switch unit and the lower device implemented by redundancy in the exchange includes a redundant time switch unit 10, an upper control unit 20, and a device block (as shown in FIG. 1). 30), wherein the time switch, which is active in the redundant time switch unit 10, transmits and receives data to and from the device block 30 under the control of the upper control unit 20. The time switch in the standby state processes the data internally under the control of the upper control unit 20, and receives only the data in the form of multiple bus reception from the device block 30.

The redundant time switch unit 10 multiplexes 32 subhighway lines applied from the device block 30 to the upper control unit 20, and demultiplexes the data applied from the upper control unit 20. Applied to the device block 30 in the form of 32 subhighways.

The upper control unit 20 controls the redundant time switch unit 10 to transmit and receive test data and service data, and the device block 30 performs serial subhighway matching with the duplicated time switch unit 10.

On the other hand, the path test structure of the above-described redundant time switch unit 10, as shown in Figure 2 of the accompanying drawings, the redundancy control unit 11, the sub-highway matching section 12 and S / W matching section 13 It is provided with.

The redundancy control unit 11 monitors and controls the redundancy state to generate a redundancy control signal related to data transmission control at subhighway matching.

The subhighway matching unit 12 transmits specific subhighway test data and service data according to the redundancy control signal of the redundancy control unit 11, and extracts time slot data of a specific position applied from the device block 30 to S. / W Send to the matching section 13 side.

The S / W matching unit 13 periodically checks the redundancy state and transmits and receives with the upper control unit 20, receives the path test data and the service data from the upper control unit 20, and the sub-highway matching unit 12. Match.

Looking at the path test operation between the time switch and the lower device in the conventional switch configured as described above are as follows.

First, assuming that one of the redundant time switch unit 10 is the time switch unit 10a in the active state and the other is described as the time switch unit 10b in the standby state, the time switch unit in the active state In 10a, data applied from the upper control unit 20 is multiplexed to transmit and receive data to the device block 30, and the time switch unit 10b in the standby state processes the data internally. It will operate in a standby state and close the transmit buffer.

As described above, a path test operation for maintenance in the exchange in the subhighway structure between the redundant time switch unit 10 and the device block 30 is briefly described. When the redundancy status information is requested to perform the path test to the / W matching unit 13, the corresponding S / W matching unit 13 sends out the redundancy state information related to the redundancy control unit itself which is periodically sent out from the redundancy control unit 11. Active or standby state information) to be reported to the upper control unit 20.

Accordingly, the upper control unit 20 checks the state of each of the time switch units 10a and 10b constituting the redundant time switch unit 10 according to the redundancy state information reported from the S / W matching unit 13 and is in an active state. A path test is requested to the time switch unit 10a.

Then, the time switch unit 10a of the active state analyzes the path test request information applied by the internal S / W matching unit 13 from the upper control unit 20 so that the corresponding path test information, that is, test data and path The specific subhighway number to be tested is applied to the subhighway matching unit 12.

Accordingly, the sub-highway matching unit 12 inserts test data into a specific subhighway channel to be path-tested according to the path test information applied from the S / W matching unit 13 and then another sub-highway channel currently in service. In addition, the data is transmitted to the device block 30 by an output control signal applied from the redundancy control unit 11, wherein each time switch unit 10a or 10b of the redundancy is present according to its redundancy state. Only the time switch unit 10a in the active state transmits the test data to the device block 30 side.

Subsequently, the subhighway matching unit 12 of the time switch unit 10a that has transmitted the test data to the device block 30 receives the test data received through a specific subhighway channel among data looped back from the corresponding device block 30. Each frame is extracted, stored in a register, and transmitted when the extraction data request from the S / W matching unit 13 is requested.

In addition, the S / W matching unit 13 that receives the test data that is the extraction data from the sub-highway matching unit 12 reports the test data to the upper control unit 20 to terminate the path test.

As described above, in the time switch path test of the conventional exchange, the current time switch managed by the redundancy control unit 11 using the S / W matching unit 13 of the time switch unit 10 in which the upper control unit 20 is duplicated. After confirming the active or standby state of the units 10a and 10b, the path test can be performed only for the time switch unit 10a in the active state, and all the paths of each redundant time switch unit 10a and 10b are tested. I could not.

By the way, while each of the redundant time switch unit 10 simultaneously processes the service data received from the upper control unit 20 internally, only the time switch unit 10a in the active state on the actual device block 30 side. As the test data and the service data are transmitted, only the path test can be performed on the time switch unit 10a in the active state, but the path test cannot be performed on the time switch unit 10b in the standby state.

Therefore, when an error occurs in the exchange and the time switch unit 10a in the active state is switched to the standby state, the redundant switchover is performed regardless of whether the time switch unit 10b in the standby state is normal or not. If the time switch unit 10b transferred to the active state is poor as the process continues, there is a problem that causes a serious failure of the service.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object thereof is to provide a standby path test function between a time switch in a standby state and a lower device without an additional subhighway matching path in a redundant time switch of an exchange. It is to improve the system diagnostic function of the exchange.

1 is a block diagram illustrating an interface device between a redundant time switch unit and a lower device in a general exchange;

2 is a block diagram illustrating a test structure of a conventional redundant time switch in FIG.

3 is a block diagram illustrating a standby path test structure in a redundant time switch unit of an exchange according to the present invention;

4 is an operational flowchart for implementing a standby time switch path test method of an exchange according to the present invention;

Explanation of symbols on the main parts of the drawings

10: duplicated time switch unit 10a: active time switch unit

10b: standby time switch unit 11, 11b: redundant control unit

12,12b: subhighway matching section 13,13b: S / W matching section

20: upper controller 30: device block

A feature of the present invention for achieving the above object is the step of applying the standby path test information for the path test from the upper control unit to the standby time switch unit; Analyzing the standby path test information to generate a corresponding standby output control signal, and notifying the subhighway matching unit that there is a path test for a specific subhighway channel; Inserting standby path test data included in the standby path test information into a specific subhighway channel to be path tested and transmitting the standby path test data to a lower device block according to the standby output control signal; A method of testing a standby time switch path of an exchange comprising extracting standby path test data looped back through a specific subhighway channel from the device block and reporting the standby time switch path to the upper control unit to determine whether the standby time switch path is normal. To provide.

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

Since the interface device between the time switch unit and the lower device implemented in redundancy in the switch according to the embodiment of the present invention has the same basic configuration as the conventional configuration shown in FIG. 1, the same reference numerals will be used.

However, the redundant time switch unit 10, the upper control unit 20, and the device block 30 applied to the present invention are different from the conventional ones in terms of their functional aspects. The sub-highway is matched with the device block 30 under the control of the upper control unit 20, and inserts and extracts active and standby path test data to the upper control unit.

The upper control unit 20 controls the redundant time switch unit 10 and transmits and receives active and standby path test data through the redundant time switch unit 10 to perform a corresponding active path and standby path test. do.

The device block 30 transmits and receives the duplicated time switch unit 10 and path test data and service data through sub-highway matching.

Meanwhile, in the path test of the redundant time switch unit 10 described above, the path test of the time switch unit 10a in the active state, that is, the active path test is the same as the conventional one, and thus description thereof will be omitted. Referring to the standby path test structure to be proposed in the accompanying drawings, as shown in FIG. 3, the redundant control unit 11b, the subhighway matching unit 12b, and the S / W matching unit 13b are provided.

The redundancy control unit 11b receives the standby time switch path control data from the S / W matching unit 13b and applies the corresponding standby path control signal and the redundancy control signal to the subhighway matching unit 12b.

The subhighway matching unit 12b performs transmission control on the path test data to the device block 30 side during the standby time switch path test according to the standby path control signal and the duplication control signal received from the duplication control unit 11a. do.

The S / W matching unit 13b receives service data from the upper control unit 20, matches with the subhighway matching unit 12b, analyzes standby path test data received from the upper control unit 20, and performs a redundancy control unit ( 11b).

Looking at the path test operation between the time switch and the lower device in the switch according to the present invention configured as described above are as follows.

First, one of the redundant time switch unit 10 is referred to as an active time switch unit 10a (hereinafter, referred to as an 'active time switch unit' for convenience of explanation), and the other is a time switch in a standby state. Assuming that the unit 10b (hereinafter, referred to as an 'active time switch unit' for convenience of description) is described, the redundant time switch unit 10 receives active and standby path test data from the upper control unit 20. After receiving the test data to the device block 30 through the specific subhighway channel to receive and test the path, the test data to be looped back is extracted and reported to the upper control unit 20, whereby the active time switch path and the standby time switch path In this case, the test operation for the active time switch path is performed. Since the operation is the same as the network operation, a description thereof will be omitted. Hereinafter, a test operation for a standby time switch path will be described with reference to FIG. 4.

The upper control unit 20 processes data for transmission buffer control separately from the duplication of the hardware time switch unit 10 in order to test the standby time switch path, and the standby time switch unit 10b. The standby path test information, that is, the standby path test start information and the test data are applied.

On the other hand, the S / W matching unit 13b in the standby time switch unit 10b checks whether the standby path test information is applied from the upper control unit 20 (step S41), and at this time, the standby path from the upper control unit 20. If the test information is not applied, the corresponding standby time switch unit 10b continues the current standby state (step S47), and performs the operation of step S41 for checking whether the standby path test information is applied.

In this state, when the standby path test information is applied from the upper control unit 20, the S / W matching unit 13b in the standby time switch unit 10b analyzes the standby path test information applied from the upper control unit 20. The corresponding standby path test control signal is generated and applied to the redundancy control unit 11b, and the subhighway matching unit 12b notifies that there is a path test for a specific subhighway channel (step S42).

Accordingly, the redundancy control unit 11b generates a standby output control signal according to the standby path test control signal applied to the S / W matching unit 13b and applies it to the subhighway matching unit 12b together with the redundancy control signal. (Step S43).

Then, the subhighway matching section 12b inserts the standby path test data into the specific subhighway channel to be tested in accordance with the standby path test control signal applied from the S / W matching section 13b (step S44). ), The path test data inserted into the specific subhighway channel is transmitted to the device block 30 in accordance with the standby output control signal applied from the duplication control unit 11b (step S45).

Subsequently, the subhighway matching unit 12b of the standby time switch unit 10b that has transmitted the test data to the device block 30 extracts the test data looped back through the specific subhighway channel from the corresponding device block 30 and S. By reporting to the upper control unit 20 through the / W matching unit 13b (step S46), the upper control unit 20 can determine whether or not the standby time switch path is normal, The test operation ends.

At this time, the standby time switch path test according to the present invention is a standby time switch unit 10b for the purpose of testing the path of the standby state for a predetermined time only for a specific subhighway channel of the 32 subhighway channels connected to the device block 30 ) And the standby time switch path test between the device block 30 and at the same time, the active time switch unit 10a enables buffer control for the remaining subhighway channels not specified in the path test according to the normal redundancy control signal. The subhighway is matched with the device block 30 side.

That is, the active time switch unit 10a performs subhighway matching with the device block 30 through a subhighway channel not specified in the path test. In this case, the standby time switch unit 10b performs an S / W matching unit ( By the standby path test control signal of 13b), the hardware redundancy control signal of the redundancy control unit 11b is ignored in the designated subhighway buffer control and is opened until the standby path test is completed.

As described above, in the present invention, the time switch unit in the current standby state is tested by testing whether the standby path between the standby time switch unit 10b and the lower device block 30 is normal under the control of the upper control unit 20. It is possible to know whether or not (10b) is normal, so that when an error occurs in the exchange and transfers the active time switch unit 10a to the standby state, only when the time switch unit 10b that is currently in the standby state is normal. You can perform the transfer and safely proceed with the corresponding service.

As described above, the present invention provides a standby path test function between a time switch in a standby state and a lower device without an additional subhighway matching path in the redundant time switch of the exchange, thereby improving the system diagnosis function of the exchange.

Claims (1)

Applying standby path test information for a path test from an upper control unit to a standby time switch unit; Analyzing the standby path test information to generate a corresponding standby output control signal and notifying the subhighway matching unit that there is a path test for a specific subhighway channel; Inserting standby path test data included in the standby path test information into a specific subhighway channel to be path tested and transmitting the standby path test data to a lower device block according to the standby output control signal; A standby time switch of the exchange, wherein the standby path switch data is extracted from the device block and is reported to the upper control unit to determine whether the standby time switch path is normal by extracting standby path test data looped back through a specific subhighway channel Path test method.