KR20030027555A - Method for controlling a frame synchronization for a E1 link - Google Patents

Abstract

According to the present invention, a criterion for deviating and recovering frame synchronization according to a state of a transmission path in an E1 link between an access gateway system and a digital exchange receiving the variable is variably applied to cope with transmission performance and an operational state of the transmission path. An improved frame synchronization control method for an E1 link, comprising: a synchronization mode for detecting a frame synchronization array signal of a received signal and a plurality of synchronizations sequentially detecting the synchronization array signal in a previous frame when the synchronization array signal is not detected; Perform a departure check mode, a search mode for searching for synchronization when no synchronization array signal is detected in the departure check mode, and a plurality of sync recovery check modes for detecting the synchronization array signal in the next frame if a frame is detected in the search mode; And the synchronization departure check mode and the synchronization recovery check mode. The number of times is adjusted according to the bit error ratio.

Therefore, there is an effect that improvement of the telephone service quality provided in the access gateway system is expected.

Description

Method for controlling a frame synchronization for a E1 link}

The present invention relates to a method for controlling frame synchronization of an E1 link. More particularly, the present invention relates to a method for determining the departure and recovery of frame synchronization according to a state of a transmission path in an E1 link between an access gateway system and a digital exchange receiving the same. The present invention relates to a method for controlling frame synchronization of an E1 link, which is improved to cope with transmission performance and operational state of a transmission path.

In general, an access gateway system relies solely on the control of a digital switch connected to an E1 (2.048 Mbps) link for call processing and other supplementary service functions of a telephone service. Therefore, the subscriber accommodated in the access gateway system uses the E1 link when using the telephone service.

Therefore, the quality of the telephone service provided by the access gateway system is greatly affected by the transmission performance of the E1 link. Therefore, in order to provide quality service to the telephone service subscribers accommodated in the access gateway system, the transmission quality of the E1 link may be improved. It must be maintained.

In this respect, effectively maintaining and managing frame synchronization of the E1 link is an essential condition for maintaining the quality of telephone service provided by the access gateway system.

However, the general method of maintaining frame synchronization of an E1 link applies a fixed standard regardless of the performance of the transmission path.

Therefore, as the criterion for determining frame synchronization departure and synchronization recovery is fixed, there is a problem that flexibility is deteriorated and the maintenance and control function of the frame synchronization function is not optimized, regardless of the state of the transmission path.

More specifically, the E1 link is divided into 32 time slots, wherein time slot "0" is used for frame synchronization, time slot "16" is used for dialing, and the remaining time slots are It is set to be used for a call.

The time slot "0" includes a frame alignment alignment signal (FAS), and the pattern of the frame synchronization alignment signal is detected for synchronization at the reception (Rx) side of the access gateway system or the digital exchange.

At this time, if the pattern is not properly detected in the synchronous mode for detecting frame synchronization, the synchronous deviation check is performed. If the pattern is not detected a predetermined number of times, the synchronous search is performed. When a pattern is detected in the synchronization search process, the process returns to the synchronization mode.

However, the conventional method described above always applies a constant reference count to the desynchronization check and the synchronous search regardless of the state where the error occurrence possibility is different.

Therefore, since the frame synchronization is not checked flexibly with respect to the state of the transmission path as described above, there is a problem that there is a limit in maintaining the quality of the telephone service provided by the access gateway system at a high level.

An object of the present invention is to control the frame synchronization of the E1 link connecting the access gateway system and the digital exchange according to the transmission path conditions.

It is another object of the present invention to apply a reference frequency for detecting frame synchronization of an E1 link connecting an access gateway system and a digital exchange and a reference frequency for recovering frame synchronization according to the state of a transmission path. This gives flexibility in synchronization control.

1 is an E1 link block diagram between an access gateway system and a digital switchgear accommodating the same according to the present invention.

2 is a diagram illustrating a state of maintaining and controlling a transmission path forming an E1 link as an embodiment of a frame synchronization control method of an E1 link according to the present invention.

The frame synchronization manufacturing method of an E1 link according to the present invention includes a synchronization mode for checking and checking a pattern of a frame synchronization array signal included in a transmission signal at a reception side of a transmission path state connecting an access gateway system and a digital switch. The desynchronization check process, the search mode, the synchronous recovery check process are performed, and the number of the desynchronization check mode and the synchronous recovery check mode included in the desynchronization check process and the synchronous recovery check process is varied according to the bit error ratio.

Hereinafter, a preferred embodiment of a method for controlling frame synchronization of an E1 link according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the access gateway system 10 forms an E1 link with the digital switch 20 with a plurality of transmission paths 30. The access gateway system 10 and the digital switch 20 include a transmitter Tx and a receiver Rx corresponding to each transmission path 30.

The E1 link (V5.2) has a transmission rate of 2.048 Mbps and has 32 time slots. The time slot "0" of these time slots includes a frame synchronization array signal having a word pattern of a format that is less likely to occur during a call to check synchronization.

Each transmission path connected to the access gateway system 10 and the digital switch 20 always has a possibility that a bit error is caused by an external influence such as EMI. For this purpose, each receiver Rx is in a state of synchronization of a received signal. Always check

A diagram for checking the synchronization state can be initiated as shown in FIG.

The check of the synchronization state according to the present invention is divided into a synchronization mode, a synchronization departure check process, a search mode, and a synchronization recovery check process.

In FIG. 2, A denotes a synchronization mode for first detecting a frame synchronization array signal of a received signal.

The desynchronization check process L1 is performed by repeating a plurality of desynchronization check modes. In FIG. 2, the desynchronization check process L1 includes the desynchronization check modes B, C, and D.

The desynchronization check mode B detects the frame synchronizing array signal in the next frame when the frame synchronizing arrangement signal is not detected in the synchronizing mode A, and the desynchronization check mode C detects the frame synchronizing array signal in the desynchronization check mode B. If not, the frame synchronization array signal is detected in the next frame, and the deviation check mode D detects the frame synchronization array signal in the next frame when the frame synchronization array signal is not detected in the synchronization departure check mode C.

Here, the number of desynchronization check modes included in the desynchronization check process L1 may be adjusted by checking the bit error ratio.

For example, if the bit error ratio is 10 ^-6 level, the desynchronization check mode can be set 3 times as B, C, D, but if the bit error ratio is 10 ^-3 level, the desynchronization check mode is B, C, It may be set four or more times including D. This eliminates the effect on frame synchronization performance due to bit error ratio.

That is, when the frame synchronization arrangement signal is detected in the above-described deviation departure checking modes B, C, and D, the synchronization mode A is returned. When the frame synchronization arrangement signal is not detected in the final deviation departure checking mode D, the detection mode E is switched.

The search mode E is determined to be out of sync as a result of repeatedly performing the out of sync check mode, and thus, searching for sync by stopping transmission to the transmission path and tracking the received frame.

In the search mode E, if the synchronization of the frame is confirmed by the synchronization of the frame, the synchronization recovery check process L2 is performed.

In the synchronous recovery check process L2, a plurality of synchronous recovery check modes are repeated, and in FIG. 2, the synchronous recovery check process L2 includes the synchronous departure check modes F and G. FIG.

The desynchronization check mode F is switched to the search mode E when the synchronization array signal of the next frame is not detected, and is switched to the desynchronization check mode F when the frame synchronization array signal of the next frame is detected. The desynchronization check mode F switches to the search mode E when the frame synchronization array signal of the next frame is not detected, and returns to the synchronization mode A when the frame synchronization array signal of the next frame is detected.

Here, the number of desynchronization check modes included in the synchronous recovery check process L2 may be checked and the number thereof may be adjusted.

For example, when the bit error ratio is 10 ^-6 level, the desynchronization check mode may be set to two times, such as F and G. However, when the bit error ratio is 10 ^-3 level, the desynchronization check mode may be set to one time. have. This eliminates the effect on frame synchronization performance due to bit error ratio.

The bit error ratio is simply calculated by dividing the number of transitions to the synchronization mode A from the desynchronization check modes B, C and D or the number of transitions to the search mode E from the synchronization recovery check modes F and G by dividing by a predetermined unit time. You can check it.

According to the present invention, by applying the bit error ratio as a parameter, the number of modes included in the desynchronization check process and the synchronous recovery check process can be adjusted according to the degree, and accordingly, the control of maintaining the frame sync state is flexible according to the transmission performance. Can be controlled.

Therefore, the frame synchronization departure and recovery is controlled according to the quality level of the transmission path, and the frame synchronization control appropriate to the transmission performance state of the E1 link is achieved, thereby improving the telephone service quality provided by the access gateway system. .

Claims (5)

A frame synchronization control method of an E1 link in which a path state connecting an access gateway system and a digital exchange is checked by checking a pattern of a frame synchronization array signal included in a transmission signal at a receiving side. A synchronization mode for detecting a frame synchronization array signal of the received signal; If the synchronization array signal is not detected in the synchronization mode, the synchronization array signal is sequentially detected in a previous frame, and when the synchronization array signal is detected in the corresponding frame, a plurality of deviation checking modes for returning to the synchronization mode are included. Out of sync check process; A search mode for searching for synchronization by tracking a frame when the synchronization alignment signal is not detected in the deviation checking process; When a frame is detected in the search mode, a plurality of sync recovery check modes for detecting the sync array signal are performed in a next frame, and when the sync array signal is detected in the last sync recovery check mode, the sync recovery check returns to the sync mode. Process; And the number of the desynchronization check mode and the sync recovery check mode is adjusted according to a bit error ratio. The method of claim 1, And increasing the bit error ratio increases the number of the desynchronization check modes, and decreases the number of the desynchronization check modes. The method of claim 1, And increasing the number of bit error ratios increases the number of the synchronization recovery check modes, and decreases the number of the synchronization recovery check modes. The method of claim 1, The bit error ratio is determined by the number of times to return from the out of synchronization check mode to the synchronization mode within a predetermined time. The method of claim 1, The bit error ratio is determined by the number of times to return to the search mode from the synchronization recovery check mode within a predetermined time.