KR19980069185A - Trunk loopback test method of switching system - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

It is a technology to perform loopback test of trunk line between stations in exchange system.

I. The technical problem to be solved by the invention

During the loopback test between CEPT trunk trunk boards, remote loopback signals may be malfunctioned to prevent looping conditions caused by transmission line faults, and only remote loopback tests of all channels are possible.

All. Summary of Solution of the Invention

When the remote loopback test request signal is generated from the transmitter, it detects the abnormal PCM channel of the trunk requesting test and receives the remote loopback test request for all channels or free channels when the PCM link is confirmed as normal. Check the test data loopbacked from the side to confirm the remote loopback test results.

la. Important uses of the invention

Applicable to the trunk loopback test of switching systems with septic trunk structure.

Description

Trunk loopback test method of switching system

The present invention relates to a trunk loopback test method of an exchange system, and more particularly, to a loopback test of a trunk line between stations in an exchange system.

In general, the remote loopback test between stations in the trunk of the CEPT trunk line of the TDX-1B switching system performs all channel remote loopback tests without checking for abnormalities on the PCM link when a test request from a large station is received.

1 is a block diagram of acept trunk of a general switching system.

Processors 10a and 10b are configured with Z80180 chips to control loop-by-channel loopback tests of the trunk. ROMs 12a and 12b store the program for the loopback test. Time switches 14a and 14b switch received test data. Sept Framers 16a and 16b consist of the MT8979 chip and are connected to the Sept type PCM line. DTCP (Digital Trunk CEPT Processor) 18a, 18b is connected to the processors 10a, 10b by IPC to generate a remote loopback test request signal to an upper processor of the digital trunk, and analyzes the received test result data to analyze the relay line transmission line. Judge any abnormality.

2 is a control flowchart for performing a loopback test of a conventional transmission-side sept type trunk;

3 is a control flowchart for performing a loopback test of a conventional receiving-side septic trunk.

1 to 3, the conventional trunk loopback test operation is described. In step 101, the DTCP 18a generates a remote loopback test request signal between stations in the online state and applies it to the processor 10a. In this case, the processor 10a proceeds to step 102 and controls the time switch 14a to transmit a remote loopback test request signal for all channels to the power station through thecept framer 16a. Thecept framer 16a sets the BIT 0,1 of time slot 0 of the ODD frame in the CEPT frame structure to request a remote loopback test to the large station. Then, in step 103, the PRBS (PSUDO RANDOM BINARY SEQUENCE) test pattern is transmitted to all stations in step 103. In step 104, the standby state is entered for 200 msec. Then, in step 107, the receiving digital trunk sends a loopback test request signal. Also, the receiving digital trunk has the same configuration as that of Fig. 1. Therefore, when the loopback test request signal is applied to the processor 10b through theceptor 16b and the time switch 14b, the processor 10b reports that the loopback test signal has been received to the DTCP 18b. In step 108, the loopback test is performed, and when the test is completed, the test status of the PCM link is reported to DTCP 18b, and the process proceeds to step 109. In step 109, the remote loopback bit is set to test data to a large station. Then, the processor 10a receiving the test result data is 1 In step 05, the data looped back from the power station is checked and the test result is reported to DTCP 18a, and the flow proceeds to step 106. In step 106, the test release signal is requested to the power station, that is, bits 0 and 1 of the NFAS are set to 11. Then, in step 110, the remote loopback test processor 18b receives the remote loopback test release signal from the power station through the septum framer 16b, performs a remote loopback test release, and proceeds to step 111. The remote loopback bit is cleared to maintain the normal path.

The conventional loopback test method of the CEPT trunk trunk board as described above does not check for abnormalities on the PCM link when the test request is received, which may cause a malfunction of the remote loopback signal, thereby causing a looping state due to an instantaneous transmission line error. Also, only remote loopback testing of all channels was possible.

If BIT 0,1 of ODD frame timeslot 0 is recognized as 0 due to the loss of the frame alignment signal, the transmission line section is looped because it is recognized as a remote loopback test request by the trunk line boards of the main station and the power station. If the hardware and software are not reset, the transmission link will not be restored normally, resulting in confusion in maintenance.

Accordingly, an object of the present invention is to provide a trunk loopback test method for performing a loopback test after checking for an abnormality on a PCM link when receiving a test request signal in order to solve the above problems.

Another object of the present invention is to provide a trunk loopback test method for eliminating looping conditions that may occur in a remote loopback test.

1 is a block diagram of a sept trunk of a general switching system

2 is a control flowchart for performing a loopback test of a conventional transmitting-side sept trunk.

3 is a control flowchart for performing a loopback test of a conventional receiving-side sept trunk.

4 is a control flowchart for a loopback test of a transmission trunk according to an embodiment of the present invention,

5 is a control flowchart for a loopback test of a receiving trunk according to an embodiment of the present invention.

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

A block diagram of a sept trunk of an exchange system according to an embodiment of the present invention is shown in FIG. 1 and the same reference numerals are used.

4 is a control flowchart for a loopback test of a transmission trunk according to an embodiment of the present invention,

5 is a control flowchart for a loopback test of a receiving trunk according to an embodiment of the present invention.

1 and 3 to 4 will be described in detail the operation of the preferred embodiment of the present invention.

The DTCP 18a generates a remote loopback test request signal between stations in the online state and applies it to the processor 10a. In step 201, the processor 10a receives the remote loopback test request signal. In this case, the processor 10a proceeds to step 202 to check whether the corresponding PCM link is in a normal state, and if the PCM link is not in a normal state, the processor 10a proceeds to step 203. In step 203, the processor 10a reports the PCM link state to the DTCP 18a. The abnormality on the PCM link checks for occurrence of a Loss Frame Alignment (LFA) or Loss Of Signal (LOS) Alarm. In step 202, if the PCM link is in a normal state, the process proceeds to step 204. The processor 10a checks whether the loopback channel to be tested is all channels (ALL-CH) or individual channels (PER-CH). . In this case, the individual channel (PER-CH) means each PCM transmission channel. In step 205, the processor 10a requests all channels of the remote loopback test to the power station B and proceeds to step 206. At this time, thecept framer 16a requests a remote loopback test to a large station using extra bits 0, 1, 2, and 3 of a multiframe alignment signal channel among CEPT frame structures for the voice channel. In step 206, the time switch 14a is controlled to transmit a PRBS (PSUDO RANDOM BINARY SEQUENCE) test pattern for all voice channels to the power station through the septum framer 16a. A bitmap requesting a test to a large station using EXTRA BIT of a multiframe alignment signal channel for remote loopback test of all the voice channels is shown in Table 1 below.

TABLE 1

BIT 7-4 BIT 3 BIT 2 BIT 1 BIT 0 FUNCTION MFAS (0000) One RSA One One NORMAL STATUS MFAS (0000) One RSA 0 0 ALL CHANNEL REMOTE TEST REQUEST MFAS (0000) 0 RSA 0 0 PER CHANNEL REMOTE TEST REQUEST MFAS (0000) One RSA One One RELEASE REQUEST

MFAS: MULTIFRAME ALIGNMENT SIGNAL (000), RSA: REMOTE SIGNAL ALARM

In step 207, the device enters the standby state for 200 msec.

Then, in step 301, the receiving side digital trunk receives the loopback test request signal. Therefore, when the loopback test request signal is applied to the processor 10b through thecept framer 16b and the time switch 14b, the processor 10b reports that the loopback test signal has been received to the DTCP. In step 302, the PCM link is checked for normal operation. If the PCM link is not in normal state, the process proceeds to step 303. In step 303, the processor 10b reports the corresponding PCM link state to the DTCP 18b. The abnormality on the PCM link checks for occurrence of a Loss Frame Alignment (LFA) or Loss Of Signal (LOS) Alarm. In step 302, if the PCM link is in a normal state, the process proceeds to step 304. The processor 10b checks whether the loopback channel to be tested is all channels (ALL-CH) or individual channels (PER-CH), and if it is all channels (ALL-CH). Proceed to step 305. In step 305, the processor 10b checks whether there is an abnormality in the PCM links of all channels, and sets the remote loopback control bits of thecept framer 16b when it is determined to be normal. In step 207, the processor 10a checks the test data looped back from the power station B, reports the test result to the DTCP 18a, and confirms it. Then, the processor 10a sends a loopback test release request signal to the power station B and terminates the program. Then, the processor 18b receives the remote loopback release signal and releases the remote loopback control bit of the framer of the corresponding PCM link.

However, if the channel to be tested in the step 204 is a separate channel (PER-CH) proceeds to step 210 and transmits the test request signal by loading the pre-channel remote loopback test and corresponding channel information on the MFAS and NFAS channels to the station B. do. In operation 211, a test pattern is loaded on a corresponding test channel and transmitted. That is, it transmits 0000 0X00 data in MULTIFRAME ALIGMENT SIGNAL CHANNAL and transmits data to select specific test channel in NON-FRAME ALIGMENT SIGNAL CHANNAL. The bitmap for PER CHANNAL REMOTE LOOPBACK test is shown in Table 2 below.

TABLE 2

BIT 7 BIT 6 BIT 5 BIT4BIT0 FUNCTION IU NFAS RJA 11011 :: 111110001 :: 1111011111 TIMESLOT 1TIMESLOT 2TIMESLOT 3 :: TIMESLOT 15TIMESLOT 17 :: TIMESLOT 30TIMESLOT 31

Where IU: INTERNATIONAL USE, NFAS: NON-FRAME ALIGNMENT SIGNAL,

RJA: REMOTE JUNCTION ALARM

Processor 10a then waits for 200msec. Then, in step 301, the receiving side digital trunk receives the loopback test request signal. Therefore, when the loopback test request signal is applied to the processor 10b through theceptor 16b and the time switch 14b, the processor 10b reports that the loopback test signal has been received to the DTCP 18b. In step 302, the PCM link is checked for normal operation. If the PCM link is not in normal state, the process proceeds to step 303. In step 303, the processor 10b reports the corresponding PCM link state to the DTCP 18b. The abnormality on the PCM link checks for occurrence of a Loss Frame Alignment (LFA) or Loss Of Signal (LOS) Alarm. In step 302, if the PCM link is in a normal state, the process proceeds to step 304. The processor 10b checks whether the loopback channel to be tested is all channels (ALL-CH) or individual channels (PER-CH). Proceed to step 307. In step 307, the test channel is checked for abnormality on the PCM link by using the time switch 14b. In step 213, the processor 10a checks the data that has been looped back, reports the test result to the DTCP 18a to confirm the test result, and proceeds to step 214. In step 214, the DTCP 18a transmits a test release request signal, for example, 00001X11, to the power station B through thecept framer 16a. Then, in step 308, when the processor 10b of the power station B receives the remote loopback test release signal through the septum framer 16b, the processor 10b reconnects the corresponding test channel with a normal pass. In this way, the remote loopback test is performed on the free channel.

As described above, the present invention can be used in all devices that are matched to the Sept transmission path, such as the E1 station device and the exchanger E1 trunk, and contribute to the standardization of the procedure for performing the functions among the devices having the same function, and are reserved on the sept frame structure. EXTRA bit and NATIONAL bit can be used as transmission line maintenance concept, and there is an advantage to prevent the holding of looping state on PCM link caused by remote loopback test.

Claims (6)

In the trunk loopback test method for all channels in a switching system, When the remote loopback test request signal is generated, the PCM channel of the trunk requesting is detected and if the normal PCM link is confirmed, the remote loopback test request is performed for all channels to check the test data that has been looped back. Trunk loopback test method of an exchange system, characterized in that the remote loopback test results are verified The method of claim 1, The loopback test for all the channels is trunk loopback test method of the switching system, characterized in that using the EXTRA bit of the multi-frame alignment signal channel. In a loopback test method for all channels between trunks in a switching system, A process of checking whether there is an abnormality of the PCM link requesting a test when a loopback test request is generated on the transmitting side; Transmitting the remote loopback test request signal for all channels with test data to the trunk of a receiver when the PCM link is normal; Checking whether a PCM link is abnormal when a test request signal is received from the transmitting side; Setting a remote loopback control bit for a corresponding test PCM link when the corresponding PCM link is in a normal state; Trunk loopback test method of the switching system, characterized in that the process of checking the data that is looped back from the receiving side to confirm the test results. The method of claim 3, The remote loopback test excitation signal is transmitted on a multi-frame alignment signal channel to transmit a trunk loopback test method. In the trunk loopback test method for an individual channel (PER-CH) in a switching system, When the remote loopback test request signal is generated from the transmitter, it detects abnormality of the PCM channel of the trunk requesting test, and if the normal PCM link is confirmed, the remote loopback test request for the individual channel (PER-CH) is sent to the receiver. Trunk loopback test method of a switching system, characterized in that by checking the test data loopbacked from the receiver side to confirm the remote loopback test results. The method of claim 5, The loopback test request signal for the individual channel (PER-CH) is a trunk loopback test method of the switching system, characterized in that for transmitting the data to select a specific test channel to the NON-FRAME ALIGNMENT SIGNAL channel.