KR100777874B1 - Removing Method of APS Receiving Error for Optical Transmission System - Google Patents

Abstract

The present invention relates to an APS of an optical transmission system, and more particularly, to an APS reception error elimination method in an optical transmission system capable of performing a stable switching operation even if an error bit exists in an APS.

According to the present invention, a first step of performing CRC on the APS data to transmit to the receiving end; A second step of transitioning from a normal state to a valid APS verification state when there is a data change in the APS data received by the receiver and a CRC error is not detected; Determining a data change in the valid APS verification state; Performing a CRC on received APS data in the valid APS verification state; A fifth step of accumulating the number N of consecutive identical received APS data only when there is no data change and a CRC error is not detected in the third and fourth steps; And a sixth step of generating an APS event when the N reaches a predetermined value δ. As a result of the above configuration, even if there is an error in the APS, unnecessary switching operation is not performed.

Optical transmission system, SDH, SONET, APS, CRC

Description

Rejecting method of APS Receiving Error for Optical Transmission System

1 is a block diagram of a general optical transmission ring system.

2 is a diagram illustrating a process of transmitting APS data that has performed CRC.

3 is a state diagram for the exclusion of APS reception error according to the present invention.

4 is a flowchart showing a method for excluding an APS reception error according to the present invention.

The present invention relates to APS (Automatic Protection Switching) of the optical transmission system, and more particularly, even if there is an error in the APS data in the optical transmission system, APS data reception in the optical transmission system to prevent the wrong transfer operation is performed Error exclusion method.

The present invention relates to an APS of an optical transmission system, but will be described with reference to the APS of an SDH (Synchronous Digital Hierarchy) optical transmission system. And, of course, the present invention can be applied to a Synchronous Optical Network (SONET) system.

In SDH (Synchronous Digital Hierarchy) optical transmission system, K1, K2 byte (hereinafter referred to as 'APS byte' or 'APS data'), which is one of the overheads of multiplexing interval of SDH frame for automatic recovery in case of optical transmission line failure Is called).

That is, the APS (Automatic Protection Switching) is an SDH switching mechanism for routing to protect the traffic of the line in use when a line card failure or an optical fiber is cut.

1 is a block diagram of a ring system which is a general SDH optical transmission system.

As shown in FIG. 1, when the optical fiber between node 1 and node 4 is disconnected, the SDH optical transmission system performs a protection switching function. Node 4 transmits a protection switching request to the APS byte and plays a role (node 1). The system of the station (node 1) interprets the received APS byte, performs an appropriate transfer operation, and also transmits the APS byte in response.

The protection switching function of the SDH optical transmission system as described above is one of the most important functions in the SDH optical transmission system, and a smooth protection switching function is performed only when the integrity of the APS byte used for the protection switching function is guaranteed.

That is, when there is a bit error in the APS byte, it is difficult to ensure proper performance of the optical transmission system protection switching function.

The following describes the protection switching function of the SDH optical transmission system according to the prior art.

Conventionally, in order to perform a smooth protection switching function of the SDH optical transmission system, when the APS byte is transmitted, it is simply multiplexed and transmitted within the multiplexing interval overhead, and the received APS byte value is the same APS byte value as three consecutive frames. Only when it is considered valid APS bytes.

That is, the transmitting side transmits the APS byte as it is without any processing. In addition, the receiving side receiving the APS byte transmitted from the transmitting side is a valid APS byte only when the received APS byte value is the same value for three consecutive frames (hereinafter, the same APS byte continuously for a specific frame is referred to as a 'valid APS byte'). If the newly received 'valid APS byte' value is different from the previous valid APS byte value, it is treated as an 'APS event'.

However, the above-described prior art method causes bit error of the APS data due to some factor (for example, noise or other optical / electrical error occurring in the unit detachment unit of the transmitting equipment) on the optical line or the transmitting / receiving equipment. Even in the case of occurrence (the same bit error in three consecutive frames), the reception side may not be able to exclude the case where the wrong APS byte value can be mistaken as a valid APS byte value.

As described above, if the receiver incorrectly recognizes an invalid APS byte value as a valid APS byte value, a problem may occur that may cause serious adverse effects on system operation by performing an unintended transfer operation.

The present invention is to solve the problems of the prior art as described above, has the following object.

That is, an object of the present invention is to provide a method for excluding an APS byte reception error in an optical transmission system for ensuring a stable switching operation of an optical transmission system by excluding bit errors that may occur in an APS byte.

In order to achieve the above object, in the SDH optical transmission system according to the present invention, the APS byte reception error elimination method includes a first step of performing cyclic redundancy checking (CRC) on the APS data and transmitting it to the receiving end; ; A second step of transitioning from a normal state to a valid APS verification state when there is a data change in the APS data received by the receiver and a CRC error is not detected; Determining a data change in the valid APS verification state; Performing a CRC on received APS data in the valid APS verification state; A fifth step of accumulating the number N of valid APS data only when there is no data change and a CRC error is not detected in the third and fourth steps; And a sixth step of generating an APS event when the N reaches a predetermined value δ.

According to the configuration as described above, even if an error occurs in the APS data, there is an advantage that can prevent unnecessary switching operation of the optical path.

In the optical transmission system according to the present invention, the APS reception error elimination method, wherein the first step is to transmit the FCS, which is data obtained by performing CRC on the APS data, to the receiver through F1 byte, which is a user reserved byte. It is characterized by.

According to the above configuration, there is an advantage that the FCS bytes can be transmitted efficiently.

In the optical transmission system according to the present invention, the APS reception error rejection method is characterized in that δ is 3.

According to the configuration as described above, there is an advantage that it is possible to reliably and quickly determine whether the valid APS data in the valid APS verification state.

The following describes in detail an embodiment of the APS byte reception error elimination method in the optical transmission system of the present invention based on the accompanying drawings.

2 is a diagram illustrating a process of transmitting and receiving an APS byte subjected to CRC in the SDH optical transmission system according to the present invention.

As shown in FIG. 2, the transmitter 10 calculates a 1-byte FCS (Frame Check Sequence) obtained by calculating CRC (Cyclic Redundancy Checking) to APS bytes (K1 bytes, K2 bytes) to be sent. In the overhead of SDH multiplexing interval, it is sent through F1 byte left as User Reserved Byte.

The receiving end 20 receiving the APS byte and the FCS byte transmitted from the transmitting end 10 performs a CRC on the received APS byte and the FCS (F1) byte, and if there is no problem in the result (that is, the transmission value). And the reception value match), it is regarded as normal APS byte.

The APS data error detection process is described in detail by performing CRC on the APS data.

The CRC sends the remainder (FCS) obtained by binary division using a generation polynomial defined in the data (K1 + K2 in the present embodiment) to be transmitted by the transmitter 10 as a divisor, The receiving end 20 divides the received data (data + FCS) into the generated polynomials and determines that there is no error if the rest is zero.

Since the generated polynomial is a factor that determines the accuracy of error detection, the selection of the generated polynomial is very important.

3 is a state diagram of the receiving side for the exclusion of APS byte reception error in the SDH optical transmission system according to the present invention.

First, the definition of a state according to the present invention will be described. As shown in FIG. 3, the term “normal state” means a state in which the APS byte received is not changed.

In addition, the 'effective APS verification state' 32 is a transitional state in which the 'APS event' is generated in the normal state, and is a valid APS byte (APS byte having the same value as a predetermined number of frames δ). Refers to the status of verifying cognition.

That is, in the algorithm state according to the present invention, there is a steady state 30, an effective APS verification state 32, and an APS event 34, and the factors transitioning to each state are APS data and CRC execution result error detection. Whether or not.

As shown in FIG. 3, if there is no change in the received APS byte, for example, if the value of the APS byte is AAAAA, the steady state 30 is maintained.                     

Then, there is ① a change in the value of the currently received APS data (that is, AAAAAB in the above example when the current received APS data value and the previous received APS data value are different), and ② a result of performing CRC on the received APS data. If not, transition from steady state to valid APS verification state.

The number of APS byte values changed in the valid APS verification state 32 is cumulatively counted. If a CRC error is detected as a result of performing CRC on the APS data received in the valid APS verification state, it immediately transitions to a normal state. This is to resume from the normal state because APS data with an error bit has no meaning as APS data.

If the cumulative calculation number of the changed APS byte value calculated in the valid APS verification state is a predetermined value (δ, the same APS value continuously), for example, δ = 3, that is, the effective APS value is previously valid If the APS data value differs from the current valid APS data value, an APS event is generated and transitions to a steady state.

Next, an APS data reception error elimination process according to the present invention will be described with reference to FIG. 4.

The APS data currently received does not change data (step 100) and maintains an effective APS data state (step 102).

In step 104, it is determined whether the data currently being received is in a normal state, and whether or not there is a change in the received APS data. For example, when the previous data is AAAAA, if the currently received APS data is B, the APS data is changed. If there is no APS data change, the steady state will be maintained (step 106).

If there is a change in the APS data, CRC is performed on the received APS data. The method of performing a CRC on a block in data is as known before application and briefly described above.

As a result of performing CRC on the received APS data with the data change, if an error is detected, the normal state is maintained. This is because, when an error bit is detected, it is meaningless as APS data judgment data. Then, there is one feature of the present invention (step 108).

If there is a change in the received APS data and at the same time no error occurs as a result of performing the CRC, as described above, the algorithm state becomes a valid APS verification state (step 110).

It is again checked whether there is a change in the received APS data in the valid APS verification state. If there is a change in the received APS data in the valid APS verification state, the flow returns to step 104, where N = 0. N is the number of times that the same APS data is continuously received and accumulated. For example, if the received APS data is BBBB, N = 4 (step 112).

Even if there is no change in the received APS data, the APS event does not occur immediately as in the prior art, and CRC is performed on the received APS data. This is because even if the received APS data is changed, the cause of the change is detected by a factor (noise, etc.) on the transmitting and receiving side.

That is, as a result of performing CRC, when the data of the transmitting side and the receiving side do not match, and a CRC error is detected, it is not a line failure, and therefore, it is not necessary to generate an APS event, and thus returns to the normal state. There is a feature of the present invention (step 114).

When the CRC error is not detected in the received APS data, the number N of APS data continuously received in the same manner is cumulatively calculated. The cumulative calculation of N is for determining whether the APS data received in the valid APS verification state is continuously and reliably received (ie, determining whether it is valid APS data) (step 116).

After calculating the N, it is determined whether the N reaches δ. The above δ is a predetermined value which is a criterion for determining whether the APS data received in the effective APS verification state is persistent or short-lived, and is set to 3 in this embodiment.

When N reaches 3, APS data received in the valid APS verification state, for example, AAAAABBB, becomes valid APS data. The definition of the valid APS data is as described above (step 118).

As a result of the determination in step 118, when N is smaller than δ, the received APS data does not become valid APS data, and the flow returns to step 104.

On the other hand, when the determination result in step 118, when N reaches the value δ, the received APS data becomes effective APS data, generates an APS event to perform the transmission line switching operation.

As described above, the present invention, by performing the CRC on the received APS data, detecting the APS data error that can occur when there is no need to change the transmission line, for example, such as an error on the transmission equipment By doing so, unnecessary APS events are not generated.

That is, unlike the prior art in which the present invention directly transitions from the 'normal state' to the 'APS event occurrence', the receiving APS is provided even when a valid APS verification state is provided in the middle and a CRC error is detected in the valid APS verification state. Even if the data is valid APS data, it is a technical point to make the transition to the steady state without generating an APS event.

The embodiments of the present invention described above are merely one embodiment of the technical idea of the present invention, and of course, other modifications can be made within the technical idea of the present invention by those skilled in the art.

According to the present invention having the above-described configuration and operation process, when a bit error occurs due to a factor on the optical line or transmission / reception equipment in the APS byte (especially, when the bit APS data bit error is the same for three consecutive frames), APS data By performing the CRC, the ATC data transmission and reception can be performed more reliably.

In addition, by performing a CRC on the APS data, there is an effect that can prevent the unwanted transmission line switching operation due to the error of the APS data, as a result, there is also an industrial use effect that the reliability of the SDH optical transmission system is increased. .

Claims (3)

A first step of performing cyclic redundancy checking (CRC) on APS (Automatic Protection Switching) data and transmitting it to a receiving end; A second step of transitioning from a normal state to a valid APS verification state when there is a data change in the APS data received by the receiver and a CRC error is not detected; Determining a data change in the valid APS verification state; Performing a CRC on received APS data in the valid APS verification state; A fifth step of accumulating the number N of valid APS data only when there is no data change and a CRC error is not detected in the third and fourth steps; And a sixth step of generating an APS event when the value N reaches a predetermined value (δ). The method of claim 1, wherein the first step, A method of eliminating APS reception errors in an optical transmission system, characterized in that a frame check sequence (FCS), which is data obtained by performing CRC on the APS data, is transmitted to a receiving end through F1 byte, which is a user reserved byte. The method of claim 1, Wherein δ is 3 APS reception error rejection method in the optical transmission system, characterized in that.

Images