KR102390893B1 - Method and device for automatic protection switching in packet transport network based on message - Google Patents

Abstract

The present invention relates to a method and device for automatic protection switchover against signal quality degradation of a switching node in a packet transport network. The disclosed method for automatic protection switchover against signal quality degradation of a switching node in a packet transport network includes: a signal quality degradation monitoring step; an automatic protection switchover message generation step; and a switching node automatic protection switchover operation performance step.

Description

Method and apparatus for automatic protection switching against signal quality degradation of switching nodes in packet forwarding network

An embodiment of the present invention relates to a method and apparatus for automatic protection switching against signal quality degradation of a switching node in a packet forwarding network.

A path used to provide services in a packet transport network (PTN) is called a tunnel, and the nodes constituting the tunnel are largely divided into end nodes and switching nodes. Here, the end node is a node to which a tunnel label is pushed or popped, and a switching node is a node to which a tunnel label is swapped.

The above packets are processed according to the label mapping information determined for each node within the tunnel section, and the label exists in the MPLS (Multi-Protocol Label Switching) header. It can be divided into Pop) and Swap.

In Push, when an MPLS header is appended to a received packet, a predetermined label value is filled, and the process of attaching the MPLS header is called 'Encapsulation'. When a pop receives a packet matching a predetermined label value, the MPLS header is removed from the packet, and the process of removing the MPLS header is called 'Decapsulation'. In Swap, when a packet matching a specified label value is received, the label value in the MPLS header of the packet is changed. Among the conditions for switching, if a failure occurs on the path, it means a failure between the physical links constituting the tunnel (path). can be divided into

The SF (Signal Fail) means a state in which the connectivity of the path to which the corresponding link belongs, such as a link down, has occurred, and the SD (Signal Degrade) is a state in which the signal quality of the path to which the corresponding link belongs is deteriorated due to more than link performance. do.

In general, the operation/operation of automatic protection switching in the packet forwarding network is performed at both end nodes of the tunnel (path) including the automatic protection switching protocol. do.

For this purpose, it is important to detect a failure on the path and transmit the detected information. Information transmitted through the adjacent node must be finally delivered to the end node. The end node performs the automatic protection switching protocol based on this information.

The automatic protection switching protocol has the following characteristics in case of path failure.

For each of SF and SD, it operates as follows according to the failure location (end node, switching node). SF performs a switch operation on the SF state regardless of the location of the failure, and finds the connectivity state of the path through CCM between end nodes. Detects LOC (Loss Of Continuity)-RDI (Remote Defect Indication) of CCM and performs automatic protection switching operation for SF status. SD performs a switch operation on the SD state when the failure location is the end node.

However, when the failure location is the switching node, the switching operation on the SD state cannot be performed because the SD state detected in the switching node cannot be transmitted to the end node.

Accordingly, a new method for delivering the corresponding information to the end node is required.

Registered Patent Publication No. 10-2088298 (Registration Date: March 06, 2020) Registered Patent Publication No. 10-2024902 (Registration Date: September 18, 2019)

An embodiment of the present invention divides the nodes constituting the path of the packet forwarding network into an end node and a switching node, detects a signal quality degradation of the switching node, and transmits the message to the end node, thereby providing a message between both end nodes. It is possible to improve the existing automatic protection switching protocol by sending and receiving information and allowing automatic protection switching operation, and by sending the information immediately upon detecting a failure occurring in any node in the packet forwarding network, so that the path switching operation is performed. Provided are a method and apparatus for automatic protection switching against signal quality degradation of a switching node in a packet forwarding network.

In the automatic protection switching method for signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention, a comparison result between CRC (Cyclic Redundancy Check) data for a packet reception direction and a preset CRC threshold value, and packet reception A signal quality degradation monitoring step of determining whether SD (Signal Degrade) has occurred for a port link of a switching node according to a comparison result between DDM (Digital Diagnostic Monitoring) data for a direction and a preset DDM threshold; When SD is generated, if the port link where SD is generated is a switching node, VSR (Vendor Specific OAM Reply) including PDU type, manufacturer's unique identification information, SD determination criteria, and SD generation or release status information at the corresponding switching node Automatic protection switching message generation step of generating a PDU as a new message; and when a VSR PDU is generated through the step of generating the automatic protection switching message, a switching node automatic protection switching operation performing step of performing an automatic protection switching operation at each end node using the generated VSR PDU and APS (Automatic Protection Switching) PDU includes

In addition, in the signal quality degradation monitoring step, when the SD determination criterion is CRC, the number of received CRCs is compared with the CRC threshold, and when the number of CRCs is greater than the CRC threshold, a CRC alert is generated and an SD generation condition by CRC is generated, If the number of CRCs is less than the CRC threshold, a CRC alarm is released and an SD release condition is generated by CRC, and in the automatic protection switching message generation step, information indicating that the type of PDU is a VSR PDU is included, and the SD criterion is CRC It is possible to generate a VSR PDU including information indicating SD by .

In addition, in the signal quality degradation monitoring step, when the SD determination criterion is DDM, the received DDM reception power level is compared with the DDM threshold, and if the DDM reception power level is lower than the DDM threshold, a DDM alarm is generated and the DDM When the DDM receive power level is higher than the DDM threshold, an SD release condition is created by DDM while canceling the DDM alarm. A VSR PDU including information indicating that the SD criterion is SD by DDM may be generated.

Also, in the step of performing the automatic protection switching operation of the switching node, when a VSR PDU is generated through the step of generating the automatic protection switching message, the generated VSR PDU is transmitted to one end node through the switching node along the packet reception direction, and one side After performing the automatic protection switching operation according to the VSR PDU at the end node, an APS PDU is generated and transmitted to the other end node through the switching node, and the automatic protection switching operation according to the APS PDU received from the other end node can be performed. .

In addition, in the signal quality degradation monitoring step, the SD for the port link of the end node according to the comparison result between the CRC data for the packet reception direction and the preset CRC threshold data, and the comparison result between the DDM data and the preset DDM threshold data It is further determined whether (Signal Degrade) has occurred, and in the step of generating the automatic protection switching message, when the port link in which the SD is generated is an end node, an Automatic Protection Switching (APS) PDU is further generated in the corresponding end node, and the automatic protection The switching method may further include an end node automatic protection switching operation performing step of performing an automatic protection switching operation in each end node using the generated APS PDU when the APS PDU is generated through the automatic protection switching message generating step. there is.

In addition, in the step of performing the automatic protection switching operation of the end node, when the APS PDU is generated through the step of generating the automatic protection switching message, the end node performs the automatic protection switching operation according to the APS PDU and then the opposite end through the switching node By delivering the APS PDU to the node, the corresponding end node can perform the automatic protection switching operation according to the APS PDU.

In the automatic protection switching apparatus for signal quality degradation of a switching node in a packet forwarding network according to another embodiment of the present invention, a comparison result between CRC (Cyclic Redundancy Check) data for a packet reception direction and a preset CRC threshold, and packet reception a signal quality degradation monitoring unit that determines whether or not a signal degradation (SD) has occurred for a port link of a switching node according to a comparison result between digital diagnostic monitoring (DDM) data for a direction and a preset DDM threshold; When SD is generated, if the port link where SD is generated is a switching node, VSR (Vendor Specific OAM Reply) including PDU type, manufacturer's unique identification information, SD determination criteria, and SD generation or release status information at the corresponding switching node an automatic protection switching message generator generating a PDU as a new message; and a switching node automatic protection switching operation performing unit that, when a VSR PDU is generated through the automatic protection switching message generating unit, performs an automatic protection switching operation at each end node using the generated VSR PDU and APS (Automatic Protection Switching) PDU do.

In addition, the signal quality degradation monitoring unit compares the number of received CRCs with the CRC threshold when the SD determination criterion is CRC, and generates a CRC alert while generating a CRC alert when the number of CRCs is greater than the CRC threshold and generates a condition for generating SD by CRC, If the number is less than the CRC threshold, the CRC alarm is canceled and an SD release condition is generated by CRC, and the automatic protection switching message generator includes information indicating that the type of PDU is a VSR PDU, and the SD criterion is based on the CRC. A VSR PDU including information indicating SD may be generated.

In addition, the signal quality degradation monitoring unit compares the received power level of the received DDM with the DDM threshold when the SD determination criterion is DDM, and generates a DDM alarm when the received power level of the DDM is lower than the DDM threshold. Information indicating that the SD generation condition is generated, and when the DDM reception power level is higher than the DDM threshold value, the DDM alarm is canceled and the SD release condition is generated by the DDM, and the automatic protection switching message generator is configured to indicate that the PDU type is a VSR PDU may generate a VSR PDU including information indicating that the SD criterion is SD by DDM.

In addition, the switching node automatic protection switching operation performing unit, when a VSR PDU is generated through the automatic protection switching message generating unit, transmits the generated VSR PDU to one end node through the switching node along the packet reception direction, and one end node After performing the automatic protection switching operation according to the VSR PDU, the APS PDU is generated and transmitted to the other end node through the switching node, and the automatic protection switching operation according to the APS PDU received from the other end node can be performed.

In addition, the signal quality degradation monitoring unit, according to the comparison result between the CRC data for the packet reception direction and the preset CRC threshold data, and the comparison result between the DDM data and the preset DDM threshold data, the SD ( Signal Degrade) is further determined, and the automatic protection switching message generating unit further generates an Automatic Protection Switching (APS) PDU at the corresponding end node when the port link in which the SD is generated is an end node, and the automatic protection switching device may further include an end node automatic protection switching operation performing unit that performs an automatic protection switching operation in each end node using the generated APS PDU when the APS PDU is generated through the automatic protection switching message generating unit.

In addition, the end node automatic protection switching operation performing unit, when an APS PDU is generated through the automatic protection switching message generating unit, performs an automatic protection switching operation according to the APS PDU at the corresponding end node, and then to the opposite end node through the switching node By delivering the APS PDU, the corresponding end node can perform the automatic protection switching operation according to the APS PDU.

According to the present invention, by detecting the signal quality degradation of the switching node and delivering the message to the end node, the message is exchanged between the end nodes and automatic protection switching operation is performed, and a failure occurring in any node of the packet forwarding network Provides an automatic protection switching method and device for signal quality degradation of a switching node in a packet forwarding network that can improve the existing automatic protection switching protocol by transmitting the information immediately after detecting can do.

1 is a diagram illustrating path duplication and node configuration in a packet forwarding network.
2 is a diagram illustrating an APS PDU format including request and state fields and priority.
3 is a flowchart showing the configuration of all steps of the automatic protection switching method against signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention.
4 is a flowchart illustrating a method of CRC monitoring and automatic protection switching message generation according to an embodiment of the present invention.
5 is a flowchart illustrating a DDM monitoring and automatic protection switching message generation method according to an embodiment of the present invention.
6 is a diagram illustrating a VSR PDU format according to an embodiment of the present invention.
7 is a flowchart illustrating a method of performing a switching node automatic protection switching operation according to an embodiment of the present invention.
8 is a flowchart illustrating an OAM PDU reception and processing method in an end node according to an embodiment of the present invention.
9 is a flowchart illustrating a method of performing an end node automatic protection switching operation according to an embodiment of the present invention.
10 is a block diagram illustrating an overall configuration of an automatic protection switching device against signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention.

Terms used in this specification will be briefly described, and the present invention will be described in detail.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

In the entire specification, when a part "includes" a certain element, this means that other elements may be further included, rather than excluding other elements, unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or software, or a combination of hardware and software. .

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Hereinafter, before describing the automatic protection switching method for signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention, basic descriptions and principles will be described to help the understanding of the present invention.

First, in order to improve the automatic protection switching function of redundant paths in the packet forwarding network, when a signal quality degradation (SD) occurs in the switching nodes constituting the tunnel (path), the corresponding information is delivered to the adjacent node in a message. At this time, the transmitted message is an OAM PDU (Operation, Administration and Maintenance Protocol Data Unit), and it is processed through the MIP (Maintenance Intermediate Point), and the message is received from the adjacent node, and it is processed as follows according to the type of the receiving node.

The switching node delivers a message to the next neighboring node according to the tunnel mapping information, and the end node performs an automatic protection switching operation for the corresponding tunnel according to the received message.

1 is a diagram illustrating path duplication and node configuration in a packet delivery network, and FIG. 2 is a diagram illustrating an APS PDU format including Request and State fields and priority.

The redundant path according to this embodiment is divided into a main (Working/Primary) path and a spare (Protection/Secondary) path as shown in FIG. 1 . The primary path means a main transmission path that processes (transmits/receives) traffic in a redundant path configuration. Conversely, if the spare path fails, the primary path can still handle traffic.

The operation of selecting a route that is the subject of traffic processing between the main route and the spare route is called switching. For example, when a route that handles traffic is changed from a primary route to a spare route, or from a spare route to a main route, the switch is said to have occurred.

The switching operation in the packet forwarding network follows the automatic protection switching protocol. Details of these protocols will be described later along with a description of the OAM (Operation, Administration and Maintenance) function.

The control function for managing (operating, maintaining, and repairing) the tunnel of the packet forwarding network is called OAM. There are several types of these OAM functions depending on the management purpose, and management/control of the tunnel (path) is made through the OAM PDU (Protocol Data Unit). This is specified.

Just as nodes constituting a tunnel are divided into end nodes and switching nodes, OAM functional units are classified into MEP (Maintenance End Point) and MIP (Maintenance Intermediate Point). MEP is a unit for processing OAM PDUs at the end node, MIP is a unit for processing OAM PDUs at the switching node, and each of MEP and MIP also has label mapping information for tunnel sections.

In order to perform OAM within the tunnel section, the corresponding OAM PDU must be processed according to the tunnel label mapping information of each section (or node). The MEP has tunnel label mapping information (Push or Pop) of the end node, and the MIP has tunnel label mapping information (Swap) of the switching node.

In the packet forwarding network, the end node configuring the tunnel processes OAM PDUs through MEP, and the switching node performs OAM functions by processing OAM PDUs through MIP.

Most of the OAM for the tunnel is performed at the end node. Representative OAM PDUs include CCM (Continuity Check Message) and APS (Automatic Protection Switching). CCM is an OAM PDU sent and received to manage connectivity between end nodes of a tunnel, and exists for each path in the tunnel (path) duplication configuration. APS is an OAM PDU sent and received for automatic protection switching between end nodes of the tunnel, and exists only in the spare path in the tunnel (path) duplication configuration.

Automatic protection switching protocol is a path control protocol to minimize traffic loss and provide continuous packet forwarding network service in case of path failure. It deals with the operation of switching between and the spare path.

The switching operation is performed by exchanging APS PDUs between both end nodes of the redundant path. Also, according to the standard, APS PDUs are sent and received through a spare path. As a result of the switching operation, the path that handles the actual traffic among the main path and the spare path is determined, and it must be the same between both end nodes of the tunnel (path). The condition for a switchover to occur is the occurrence of a fault on the path or an operator command.

The Request/State field of the APS PDU is where the switchover condition is reflected, and indicates a request for switchover or the final state (State). In accordance with the standard, the values and priorities corresponding to each condition are defined as shown in Fig. 2, and more specifically, the larger the field value, the higher the priority, and when a changeover condition (Request) occurs at the end node , the final state is determined with a higher priority compared to the current state, and the switching operation is performed according to the determined final state, and the result is reflected in the APS PDU and delivered to the end node of the game. In this case, the APS PDU includes information such as the final state and the current traffic route, and the opposite end node performs a suitable switching operation through the received APS PDU information.

3 is a flowchart showing the overall configuration of steps for a method for automatic protection switching against signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention, and FIG. 4 is a CRC monitoring according to an embodiment of the present invention. And it is a flow chart shown to explain a method of generating an automatic protection switching message according thereto, FIG. 5 is a flowchart illustrating DDM monitoring and a method for generating an automatic protection switching message according thereto according to an embodiment of the present invention, and FIG. 6 is this It is a diagram showing a VSR PDU format according to an embodiment of the present invention, FIG. 7 is a flowchart illustrating a method for performing a switching node automatic protection switching operation according to an embodiment of the present invention, and FIG. 8 is an embodiment of the present invention It is a flowchart illustrating a method of receiving and processing an OAM PDU in an end node according to an example, and FIG. 9 is a flowchart illustrating a method of performing an automatic protection switching operation of an end node according to an embodiment of the present invention.

Referring to FIG. 3 , in the automatic protection switching method ( S1000 ) for signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention, an end node at both ends and a switching connected by a redundant path between the end nodes A method for automatic protection switching of a packet forwarding network composed of nodes, comprising: monitoring signal quality degradation (S100), generating an automatic protection switching message (S200), performing a switching node automatic protection switching operation (S300), and automatic protection of the end node It may include at least one of performing the switching operation ( S400 ).

In the signal quality degradation monitoring step (S100), it is determined whether SD (Signal Degrade) has occurred for the port link of the switching node according to the comparison result between CRC (Cyclic Redundancy Check) data for the packet reception direction and preset CRC threshold data. and whether or not SD (Signal Degrade) has occurred in the port link of the end node can be determined according to the comparison result between the DDM (Digital Diagnostic Monitoring) data for the packet reception direction and the preset DDM threshold data.

In this signal quality degradation monitoring step (S100), first, the link state is detected in the switching node constituting the tunnel (path), and it is determined whether signal quality deterioration (SD) has occurred by looking at the link state received to the switching node, and the signal CRC (Cyclic Redundancy Check) and DDM (Digital Diagnostic Monitoring) are used as criteria for judging SD. In this signal quality degradation monitoring step (S100), the monitored target corresponds to the link connected to the port of the node used as the tunnel interface of the packet forwarding network. A method of comparing signal quality degradation data with a threshold is applied.

When the SD determination criterion is CRC in the signal quality degradation monitoring step (S100), as shown in FIG. 4 , the number of received CRCs and the CRC threshold are compared (S110a) and if the number of CRCs is greater than the CRC threshold, a CRC alert is generated while An SD generation condition by CRC is generated (S120a), and when the number of CRCs is less than the CRC threshold, a CRC alarm is released and an SD release condition by CRC can be generated (S130a). As such, in the case of port CRC monitoring, if the state in which the number of CRCs received in the link is greater than the CRC threshold set in the node continues, a CRC alarm is generated, which becomes an SD generation condition, and vice versa, an SD release condition.

In addition, in the signal quality degradation monitoring step (S100), when the SD determination criterion is DDM, as shown in FIG. 5 , the received power level of the received DDM and the DDM threshold are compared (S110b) to determine the DDM reception power level. If it is lower than the threshold, it generates a DDM alarm and creates an SD occurrence condition by DDM (S120b). If the DDM receive power level is higher than the DDM threshold, it releases the DDM alarm and creates an SD release condition by DDM (S130b). there is. As such, in the case of port DDM monitoring, if the receive power level of the optical module is lower than the receive power threshold set in the node, a DDM alarm is generated, which becomes an SD generation condition, and vice versa, it becomes an SD release condition.

In the automatic protection switching message generation step (S200), when SD is generated, if the port link where SD is generated is a switching node, the type of PDU, manufacturer's unique identification information, SD determination criteria, SD generation or release status at the corresponding switching node A Vendor Specific OAM Reply (VSR) PDU including information of may be generated as a new message. In this case, in the VSR PDU, the type of PDU may include information indicating that it is a VSR PDU, and the SD criterion may include information indicating that it is SD by CRC and DDM.

The VSR PDU according to this embodiment uses a Vendor Specific OAM Reply (VSR) PDU, which is a type of OAM PDU, as a new message to contain link state information, and the format of the message is specified in the standard ITU-T G.8113.1. as shown in FIG. 6 .

Referring to FIG. 6 , information filled in a VSR PDU is as follows, and some fields (SubOpCode, VSR Data) follow User Defined.

1) MEL (3-bit): MEG Level <0-7>

2) Version (5-bit): 0

3) OpCode (8-bit): 0x32 (means that OAM PDU is VSR PDU, defined in standard ITU-T G.8113.1)

4) Flags (8-bit): 0

5) TLV Offset (8-bit): 5

6) OUI (24-bit): Manufacturer's unique identification number, 0x000E5A (This is a field that identifies the VSR PDU related to the automatic protection switching protocol).

7) SubOpCode (8-bit): Indicates whether the SD judgment criterion is CRC or DDM (If the corresponding field value is 2, it means that the SD state by CRC is detected. If the corresponding field value is 3, it indicates SD by DDM. means it has detected a condition).

8) VSR Data (24-bit): Indicates the SD generation or release status (if the corresponding field value is 1, it means SD has occurred, and if the corresponding field value is 0, it means SD is released).

9) End TLV (8-bit): 0

A new message for automatic protection changeover of a switching node according to the present embodiment is processed according to the OAM unit set in the corresponding node. Here, since the OAM unit is a switching node, it becomes a MIP, and the MIP contains label mapping information (Swap) for a tunnel section. After the corresponding new message is generated, the corresponding message is delivered to the neighbor node through the MIP. Here, the neighbor node means the next node along the direction of the received link state, and the message is not transmitted in the reverse direction (previous node) of the reception direction. Receives a message from an adjacent node. In the case of a switching node, the message is transferred to the next adjacent node by swapping the tunnel label. In the case of an end node, after popping the tunnel label, it is added to the received message information (VSR PDU). According to it, automatic protection switching operation is performed for the corresponding tunnel (path).

In addition, in the automatic protection switching message generation step ( S200 ), when SD is generated, if the port link in which the SD is generated is an end node, an Automatic Protection Switching (APS) PDU may be generated in the corresponding end node.

In the switching node automatic protection switching operation performing step S300, when a VSR PDU is generated through the automatic protection switching message generating step S200, the automatic protection switching operation is performed at each end node using the generated VSR PDU and APS PDU. More specifically, when the VSR PDU is generated through the automatic protection switching message generation step (S200), the generated VSR PDU is transmitted to one end node through the switching node along the packet reception direction, and the one end node After the node performs the automatic protection switching operation according to the VSR PDU, an APS PDU is generated and transmitted to the other end node through the switching node, and the automatic protection switching operation according to the APS PDU received from the other end node can be performed.

For example, as shown in FIG. 7 , starting with the port signal quality degradation monitoring in the switching node B, the switching node automatic protection switching operation is performed by the switching node B, the switching node C, the end node Z, the switching node C, the switching node B, End node A will be described in order.

First, the switching node B monitors the port signal quality degradation, and the reception direction is from the end node A to the switching node B, and it can be processed according to the SD generation or release condition. Since node B is a switching node, it generates a VSR PDU and transmits it to the adjacent node C, and status information on SD generation or release can be reflected in each field (OpCode, OUI, SubOpCode, VSR Data) of the VSR PDU.

Next, the switching node C receives the VSR PDU from the switching node B, and since the C node is a switching node, the received VSR PDU may be delivered to the adjacent node Z as it is.

Next, the end node Z receives the VSR PDU from the switching node C, performs an automatic protection switching operation according to the SD status (SD occurrence or release) according to the received VSR PDU, and then sends an APS PDU according to the corresponding automatic protection switching protocol. It can generate and deliver the generated APS PDU to the adjacent node C. At this time, the final destination of the generated APS PDU becomes the end node A.

Next, the switching node C receives the APS PDU from the end node Z, and since the corresponding node is a switching node, it can forward the received APS PDU to the neighboring node B as it is.

Next, the switching node B receives the APS PDU from the switching node C, and since the corresponding node is a switching node, the received APS PDU can be delivered to the adjacent node A as it is.

Next, the end node A receives the APS PDU from the switching node B, and since the node is an end node, an automatic protection switching operation according to the received APS PDU may be performed.

In the reception message processing procedure for OAM PDUs (VSR PDUs, APS PDUs) used for automatic protection switching according to this embodiment, OAM PDUs can be distinguished by checking whether they are VSR PDUs by looking at the OpCode value. Thereafter, in determining the SD state, a switching operation for SD generation or release may be performed through the OUI, SubOpCode, and VSR Date information of the VSR PDU. In this case, OUI and SubOpCode are used to check whether the SD determination criterion is CRC or DDM, and VSR Data can be used to check whether SD is generated or released. In addition, when processing the changeover operation, the SD status and the reason for the change are displayed together, and as the reason for the change, it is possible to indicate whether it is a change by CRC or a change by DDM.

For example, if the method of processing the received message of the OAM PDU is described in more detail, as shown in FIG. 8, the type of the received OAM PDU is classified into an OpCode, and processing for the corresponding OAM function is performed according to this value. can be done In the processing of the received message VSR PDU, when the OpCode is 0x32 (S10), it is determined whether information about the SD state is included through the OUI and SubOpCode fields (S20). If the information on the SD status is correct (S30), automatic protection switching processing is performed (S40, S50), and after determining whether SD occurs and whether the SD status is CRC or DDM, automatic protection of the SD status Perform a transfer operation. SD status information can be checked through the SubOpCode and VSR Data fields. If there is no information on the SD state (S30), processing for OAM functions other than automatic protection switching is performed (S60).

In the processing of the received message APS PDU, if the OpCode is 0x27, the switching status of the opposite (counter-counter) end node is checked. The request or state information (Request/State) for switching, the path processing the actual traffic is checked, the switching status between both end nodes is checked, and an appropriate automatic protection switching process is performed (S70). In this case, it can operate according to the existing automatic protection switching protocol, and automatic protection switching processing can be performed according to each received message (VSR, APS). At this time, an APS PDU is generated for the automatic protection switching operation and the result, and the generated APS PDU is transmitted to the end node of the large station (S50).

In the end node automatic protection switching operation performing step (S400), when an APS PDU is generated through the automatic protection switching message generating step (S200), the automatic protection switching operation can be performed at each end node using the generated APS PDU. there is.

More specifically, in the end node automatic protection switching operation performing step S400, when an APS PDU is generated through the automatic protection switching message generating step S200, the automatic protection switching operation according to the APS PDU is performed in the corresponding end node. Then, the APS PDU is delivered to the opposite end node through the switching node, so that the corresponding end node can perform an automatic protection switching operation according to the APS PDU.

For example, when the automatic protection switching operation performing step (S400) at the end node is described with reference to FIG. 9, first, the end node A monitors port signal quality degradation (reception direction is from the switching node B to the end node A direction). After that, it is processed according to the SD occurrence or release condition. Since the node where SD is generated is the end node, automatic protection switching operation is performed according to the SD status (SD generation or release), and then APS PDU is generated according to the automatic protection switching protocol and delivered to the adjacent node B. In this case, the final destination of the corresponding APS PDU becomes the end node Z.

Next, the switching node B receives the APS PDU from the end node A, and since the corresponding node is a switching node, it can forward the received APS PDU to the adjacent node C as it is.

Next, the switching node C receives the APS PDU from the switching node B, and since the node is a switching node, the received APS PDU can be delivered to the neighboring node Z as it is.

Next, the end node Z receives the APS PDU from the switching node C, and since the node is the end node, the automatic protection switching operation according to the SD state can be performed according to the received APS PDU.

10 is a block diagram illustrating an overall configuration of an automatic protection switching device against signal quality degradation of a switching node in a packet forwarding network according to an embodiment of the present invention.

Referring to FIG. 10 , the automatic protection and switching device 1000 for signal quality degradation of a switching node in a packet forwarding network according to another embodiment of the present invention includes an end node at both ends and a switching connected between the end nodes through a redundant path. A method for automatic protection switching of a packet forwarding network composed of nodes, comprising: a signal quality degradation monitoring unit 100, an automatic protection switching message generator 200, a switching node automatic protection switching operation performing unit 300, and automatic protection of end nodes At least one of the switching operation performing unit 400 may be included.

The signal quality degradation monitoring unit 100 determines whether or not SD (Signal Degrade) has occurred for the port link of the switching node according to a comparison result between CRC (Cyclic Redundancy Check) data for the packet reception direction and preset CRC threshold data. and whether or not SD (Signal Degrade) has occurred in the port link of the end node can be determined according to the comparison result between the DDM (Digital Diagnostic Monitoring) data for the packet reception direction and the preset DDM threshold data.

The signal quality deterioration monitoring unit 100 first detects the link state in the switching nodes constituting the tunnel (path), and determines whether signal quality deterioration (SD) has occurred by looking at the link state received by the switching node, and signals CRC (Cyclic Redundancy Check) and DDM (Digital Diagnostic Monitoring) are used as criteria for judging SD. The target monitored by the signal quality degradation monitoring unit 100 corresponds to a link connected to a port of a node used as a tunnel interface of the packet forwarding network. A method of comparing signal quality degradation data with a threshold is applied.

When the SD determination criterion in the signal quality degradation monitoring unit 100 is CRC, as shown in FIG. 4 , the number of received CRCs is compared with the CRC threshold (S110a), and when the number of CRCs is greater than the CRC threshold, a CRC alert is generated while An SD generation condition by CRC is generated (S120a), and when the number of CRCs is less than the CRC threshold, a CRC alarm is released and an SD release condition by CRC can be generated (S130a). As such, in the case of port CRC monitoring, if the state in which the number of CRCs received in the link is greater than the CRC threshold set in the node continues, a CRC alarm is generated, which becomes an SD generation condition, and vice versa, an SD release condition.

In addition, when the SD determination criterion is DDM, the signal quality degradation monitoring unit 100 compares the received power level of the received DDM with the DDM threshold ( S110b ) to determine the DDM reception power level as shown in FIG. 5 . If it is lower than the threshold, it generates a DDM alarm and creates an SD occurrence condition by DDM (S120b). If the DDM receive power level is higher than the DDM threshold, it releases the DDM alarm and creates an SD release condition by DDM (S130b). there is. As such, in the case of port DDM monitoring, if the receive power level of the optical module is lower than the receive power threshold set in the node, a DDM alarm is generated, which becomes an SD generation condition, and vice versa, it becomes an SD release condition.

The automatic protection switching message generating unit 200, when SD is generated, when the port link where SD is generated is a switching node, the type of PDU at the corresponding switching node, manufacturer's unique identification information, SD determination criteria, SD generation or release state A Vendor Specific OAM Reply (VSR) PDU including information of may be generated as a new message. In this case, in the VSR PDU, the type of PDU may include information indicating that it is a VSR PDU, and the SD criterion may include information indicating that it is SD by CRC and DDM.

The VSR PDU according to this embodiment uses a Vendor Specific OAM Reply (VSR) PDU, which is a type of OAM PDU, as a new message to contain link state information, and the format of the message is specified in the standard ITU-T G.8113.1. as shown in FIG. 6 .

Referring to FIG. 6 , information filled in a VSR PDU is as follows, and some fields (SubOpCode, VSR Data) follow User Defined.

1) MEL (3-bit): MEG Level <0-7>

2) Version (5-bit): 0

3) OpCode (8-bit): 0x32 (means that OAM PDU is VSR PDU, defined in standard ITU-T G.8113.1)

4) Flags (8-bit): 0

5) TLV Offset (8-bit): 5

6) OUI (24-bit): Manufacturer's unique identification number, 0x000E5A (This is a field that identifies the VSR PDU related to the automatic protection switching protocol).

7) SubOpCode (8-bit): Indicates whether the SD judgment criterion is CRC or DDM (If the corresponding field value is 2, it means that the SD state by CRC is detected. If the corresponding field value is 3, it indicates SD by DDM. means it has detected a condition).

8) VSR Data (24-bit): Indicates the SD generation or release status (if the corresponding field value is 1, it means SD has occurred, and if the corresponding field value is 0, it means SD is released).

9) End TLV (8-bit): 0

A new message for automatic protection changeover of a switching node according to the present embodiment is processed according to the OAM unit set in the corresponding node. Here, since the OAM unit is a switching node, it becomes a MIP, and the MIP contains label mapping information (Swap) for a tunnel section. After the corresponding new message is generated, the corresponding message is delivered to the neighbor node through the MIP. Here, the neighbor node means the next node along the direction of the received link state, and the message is not transmitted in the reverse direction (previous node) of the reception direction. Receives a message from an adjacent node. In the case of a switching node, the message is transferred to the next adjacent node by swapping the tunnel label. In the case of an end node, after popping the tunnel label, it is added to the received message information (VSR PDU). According to it, automatic protection switching operation is performed for the corresponding tunnel (path).

In addition, when the SD is generated, the automatic protection switching message generating unit 200 may generate an Automatic Protection Switching (APS) PDU in the corresponding end node when the port link in which the SD is generated is an end node.

The switching node automatic protection switching operation performing unit 300, when a VSR PDU is generated through the automatic protection switching message generating unit 200, uses the generated VSR PDU and APS PDU to perform an automatic protection switching operation at each end node. More specifically, when the VSR PDU is generated through the automatic protection switching message generating unit 200, the generated VSR PDU is transmitted to one end node through the switching node along the packet reception direction, and the one end node After the node performs the automatic protection switching operation according to the VSR PDU, an APS PDU is generated and transmitted to the other end node through the switching node, and the automatic protection switching operation according to the APS PDU received from the other end node can be performed.

For example, as shown in FIG. 7 , starting with the port signal quality degradation monitoring in the switching node B, the switching node automatic protection switching operation is performed by the switching node B, the switching node C, the end node Z, the switching node C, the switching node B, End node A will be described in order.

First, the switching node B monitors the port signal quality degradation, and the reception direction is from the end node A to the switching node B, and it can be processed according to the SD generation or release condition. Since node B is a switching node, it generates a VSR PDU and transmits it to the adjacent node C, and status information on SD generation or release can be reflected in each field (OpCode, OUI, SubOpCode, VSR Data) of the VSR PDU.

Next, the switching node C receives the VSR PDU from the switching node B, and since the C node is a switching node, the received VSR PDU may be delivered to the adjacent node Z as it is.

Next, the end node Z receives the VSR PDU from the switching node C, performs an automatic protection switching operation according to the SD status (SD occurrence or release) according to the received VSR PDU, and then sends an APS PDU according to the corresponding automatic protection switching protocol. It can generate and deliver the generated APS PDU to the adjacent node C. At this time, the final destination of the generated APS PDU becomes the end node A.

Next, the switching node C receives the APS PDU from the end node Z, and since the corresponding node is a switching node, it can forward the received APS PDU to the neighboring node B as it is.

Next, the switching node B receives the APS PDU from the switching node C, and since the corresponding node is a switching node, the received APS PDU can be delivered to the neighboring node A as it is.

Next, the end node A receives the APS PDU from the switching node B, and since the node is an end node, an automatic protection switching operation according to the received APS PDU may be performed.

In the reception message processing procedure for OAM PDUs (VSR PDUs, APS PDUs) used for automatic protection switching according to this embodiment, OAM PDUs can be distinguished by checking whether they are VSR PDUs by looking at the OpCode value. Thereafter, in determining the SD state, a switching operation for SD generation or release may be performed through the OUI, SubOpCode, and VSR Date information of the VSR PDU. In this case, OUI and SubOpCode are used to check whether the SD determination criterion is CRC or DDM, and VSR Data can be used to check whether SD is generated or released. In addition, when processing the changeover operation, the SD status and the reason for the change are displayed together, and as the reason for the change, it is possible to indicate whether it is a change by CRC or a change by DDM.

For example, if the method of processing the received message of the OAM PDU is described in more detail, as shown in FIG. 8, the type of the received OAM PDU is classified into an OpCode, and processing for the corresponding OAM function is performed according to this value. can be done In the processing of the received message VSR PDU, when the OpCode is 0x32 (S10), it is determined whether information about the SD state is included through the OUI and SubOpCode fields (S20). If the information on the SD status is correct (S30), automatic protection switching processing is performed (S40, S50), and after determining whether SD occurs and whether the SD status is CRC or DDM, automatic protection of the SD status Perform a transfer operation. SD status information can be checked through the SubOpCode and VSR Data fields. If there is no information on the SD state (S30), processing for OAM functions other than automatic protection switching is performed (S60).

In the processing of the received message APS PDU, if the OpCode is 0x27, the switching status of the opposite (counter-counter) end node is checked. The request or state information (Request/State) for switching, the path processing the actual traffic is checked, the switching status between both end nodes is checked, and an appropriate automatic protection switching process is performed (S70). In this case, it can operate according to the existing automatic protection switching protocol, and automatic protection switching processing can be performed according to each received message (VSR, APS). At this time, an APS PDU is generated for the automatic protection switching operation and the result, and the generated APS PDU is transmitted to the end node of the large station (S50).

The end-node automatic protection switching operation performing unit 400, when an APS PDU is generated through the automatic protection switching message generating unit 200, uses the generated APS PDU to perform the automatic protection switching operation at each end node. there is.

More specifically, the end node automatic protection switching operation performing unit 400, when an APS PDU is generated through the automatic protection switching message generating unit 200, performs an automatic protection switching operation according to the APS PDU in the corresponding end node. Then, the APS PDU is delivered to the opposite end node through the switching node, so that the corresponding end node can perform an automatic protection switching operation according to the APS PDU.

For example, when the end node automatic protection switching operation performing unit 400 is described with reference to FIG. 9 , first, the end node A monitors port signal quality deterioration (reception direction is from the switching node B to the end node A direction), and then , process according to SD occurrence or release conditions. Since the node where SD is generated is the end node, automatic protection switching operation is performed according to the SD status (SD generation or release), and then APS PDU is generated according to the automatic protection switching protocol and delivered to the adjacent node B. In this case, the final destination of the corresponding APS PDU becomes the end node Z.

Next, the switching node B receives the APS PDU from the end node A, and since the corresponding node is a switching node, it can forward the received APS PDU to the adjacent node C as it is.

Next, the switching node C receives the APS PDU from the switching node B, and since the node is a switching node, the received APS PDU can be delivered to the neighboring node Z as it is.

Next, the end node Z receives the APS PDU from the switching node C, and since the node is the end node, the automatic protection switching operation according to the SD state can be performed according to the received APS PDU.

The automatic protection switching protocol in the packet forwarding network according to this embodiment uses the automatic protection switching protocol to control the path of the packet forwarding network and provide continuous service, and converts the nodes constituting the path to the end node and the switching node. The automatic protection switching operation is performed by exchanging messages between the two end nodes. At this time, it is necessary to detect the occurrence of a failure in the path (SF or SD) and a prompt switching operation accordingly. have an effect

At this time, the weakness of the existing automatic protection switching protocol is that it cannot perform the switching operation processing for the SD state. Specifically, when the failure location is a switching node, both end nodes recognize this information. In this case, the switching operation does not occur, and as a result, the quality, stability and reliability of the service provided by the packet forwarding network is deteriorated.

However, according to the present embodiment, the performance of the existing automatic protection switching protocol is improved by providing the SD state switching function regardless of the location of the failure, thereby improving the quality, stability, and quality of the service provided by the packet delivery network. reliability can be increased.

What has been described above is only one embodiment for implementing the automatic protection switching method and apparatus for signal quality degradation of a switching node in a packet forwarding network according to the present invention, and the present invention is not limited to the above embodiment, As claimed in the claims, it will be said that the technical spirit of the present invention exists to the extent that various modifications can be made by anyone with ordinary knowledge in the field to which the invention pertains without departing from the gist of the present invention.

S1000: Automatic protection changeover method
S100: Signal quality degradation monitoring stage
S200: Automatic protection switchover message generation step
S300: Switching node automatic protection transfer operation execution stage
S400: End node automatic protection switchover operation step
1000: automatic protection changeover device
100: signal quality degradation monitoring unit
200: automatic protection switching message generator
300: switching node automatic protection switching operation performing unit
400: End node automatic protection switching operation performing unit

Claims (12)

In the automatic protection switching method of a packet forwarding network consisting of end nodes at both ends and a switching node connected by a redundant path between the end nodes, the method comprising:
According to the comparison result between the CRC (Cyclic Redundancy Check) data for the packet reception direction and the preset CRC threshold, and the comparison result between the DDM (Digital Diagnostic Monitoring) data for the packet reception direction and the preset DDM threshold, the port link of the switching node Signal degradation monitoring step of determining whether SD (Signal Degrade) has occurred;
When SD is generated, if the port link where SD is generated is a switching node, VSR (Vendor Specific OAM Reply) including PDU type, manufacturer's unique identification information, SD determination criteria, and SD generation or release status information at the corresponding switching node Automatic protection switching message generation step of generating a PDU as a new message; and
When the VSR PDU is generated through the automatic protection switching message generation step, the switching node automatic protection switching operation performing step of performing the automatic protection switching operation at each end node using the generated VSR PDU and APS (Automatic Protection Switching) PDU Automatic protection switching method against signal quality degradation of a switching node in a packet forwarding network, comprising:
According to claim 1,
In the signal quality degradation monitoring step,
When the SD criterion is CRC, the number of received CRCs is compared with the CRC threshold, and when the number of CRCs is greater than the CRC threshold, a CRC alarm is generated and an SD generation condition by CRC is generated, and when the number of CRCs is less than the CRC threshold, a CRC alarm while releasing the SD release condition by CRC,
In the step of generating the automatic protection switching message,
Automatic protection against signal quality degradation of a switching node in a packet delivery network, wherein the type of PDU includes information indicating that it is a VSR PDU, and the SD criterion generates a VSR PDU including information indicating that it is SD by CRC Alternate method.
According to claim 1,
In the signal quality degradation monitoring step,
When the SD criterion is DDM, the received DDM receive power level is compared with the DDM threshold. When the reception power level is higher than the DDM threshold, the DDM alarm is released and an SD release condition is generated by DDM,
In the step of generating the automatic protection switching message,
Automatic protection against signal quality degradation of a switching node in a packet delivery network, wherein the type of PDU includes information indicating that it is a VSR PDU, and the SD criterion generates a VSR PDU including information indicating that it is SD by DDM Alternate method.
According to claim 1,
The step of performing the switching node automatic protection switching operation includes:
When the VSR PDU is generated through the automatic protection switching message generation step, the generated VSR PDU is transmitted to one end node through a switching node along the packet reception direction, and the automatic protection switching operation according to the VSR PDU is performed at the one end node. After the APS PDU is generated and transmitted to the other end node through the switching node, automatic protection switching operation is performed according to the APS PDU received from the other end node. For automatic protection switching method.
According to claim 1,
The signal quality degradation monitoring step includes:
According to the comparison result between the CRC data for the packet reception direction and the preset CRC threshold data, and the comparison result between the DDM data and the preset DDM threshold data, it is further determined whether or not SD (Signal Degrade) has occurred for the port link of the end node, and ,
The step of generating the automatic protection switchover message comprises:
If the port link on which SD is generated is an end node, an APS (Automatic Protection Switching) PDU is further generated at the end node,
The automatic protection switching method is
When an APS PDU is generated through the automatic protection switching message generating step, the end node automatic protection switching operation performing step of performing an automatic protection switching operation in each end node using the generated APS PDU packet, characterized in that it further comprises Automatic protection switching method against signal quality degradation of switching nodes in the transport network.
6. The method of claim 5,
The step of performing the automatic protection switching operation of the end node,
When an APS PDU is generated through the automatic protection switching message generation step, the corresponding end node performs an automatic protection switching operation according to the APS PDU, and then delivers the APS PDU to the opposite end node through the switching node, and the APS PDU from the corresponding end node An automatic protection switching method for signal quality degradation of a switching node in a packet forwarding network, characterized in that the automatic protection switching operation is performed according to
In the automatic protection switching device of a packet forwarding network consisting of end nodes at both ends and a switching node connected by a redundant path between the end nodes,
According to the comparison result between CRC (Cyclic Redundancy Check) data for the packet reception direction and a preset CRC threshold, and the comparison result between DDM (Digital Diagnostic Monitoring) data for the packet reception direction and the preset DDM threshold, the port link of the switching node a signal quality degradation monitoring unit that determines whether or not SD (Signal Degrade) has occurred;
When SD is generated, if the port link where SD is generated is a switching node, VSR (Vendor Specific OAM Reply) including PDU type, manufacturer's unique identification information, SD determination criteria, and SD generation or release status information at the corresponding switching node an automatic protection switching message generator generating a PDU as a new message; and
When a VSR PDU is generated through the automatic protection switching message generator, a switching node automatic protection switching operation performing unit that performs an automatic protection switching operation at each end node using the generated VSR PDU and APS (Automatic Protection Switching) PDU Automatic protection switching device against signal quality degradation of a switching node in a packet forwarding network, characterized in that.
8. The method of claim 7,
The signal quality degradation monitoring unit,
When the SD criterion is CRC, the number of received CRCs is compared with the CRC threshold, and when the number of CRCs is greater than the CRC threshold, a CRC alarm is generated and an SD generation condition by CRC is generated, and when the number of CRCs is less than the CRC threshold, a CRC alarm while releasing the SD release condition by CRC,
The automatic protection switching message generating unit,
Automatic protection against signal quality degradation of a switching node in a packet delivery network, wherein the type of PDU includes information indicating that it is a VSR PDU, and the SD criterion generates a VSR PDU including information indicating that it is SD by CRC transfer device.
8. The method of claim 7,
The signal quality degradation monitoring unit,
When the SD criterion is DDM, the received DDM receive power level is compared with the DDM threshold. When the reception power level is higher than the DDM threshold, the DDM alarm is released and an SD release condition is generated by DDM,
The automatic protection switching message generating unit,
Automatic protection against signal quality degradation of a switching node in a packet delivery network, wherein the type of PDU includes information indicating that it is a VSR PDU, and the SD criterion generates a VSR PDU including information indicating that it is SD by DDM transfer device.
8. The method of claim 7,
The switching node automatic protection switching operation performing unit,
When a VSR PDU is generated through the automatic protection switching message generator, the generated VSR PDU is transmitted to one end node through a switching node along the packet reception direction, and the automatic protection switching operation according to the VSR PDU is performed at the one end node. Thereafter, APS PDU is generated and delivered to the other end node through the switching node, and automatic protection switching operation is performed according to the APS PDU received from the other end node. Automatic protection changeover device.
8. The method of claim 7,
The signal quality degradation monitoring unit,
According to the comparison result between the CRC data for the packet reception direction and the preset CRC threshold data, and the comparison result between the DDM data and the preset DDM threshold data, it is further determined whether or not SD (Signal Degrade) has occurred for the port link of the end node, and ,
The automatic protection switching message generating unit,
If the port link on which SD is generated is an end node, an APS (Automatic Protection Switching) PDU is further generated at the end node,
The automatic protection switching device is
When an APS PDU is generated through the automatic protection switching message generating unit, an end node automatic protection switching operation performing unit for performing an automatic protection switching operation in each end node using the generated APS PDU. Automatic protection changeover device against signal degradation in switching nodes in
12. The method of claim 11,
The end node automatic protection switching operation performing unit,
When an APS PDU is generated through the automatic protection switching message generator, the corresponding end node performs an automatic protection switching operation according to the APS PDU, and then delivers the APS PDU to the opposite end node through the switching node, and the corresponding end node sends the APS PDU An automatic protection switching device against signal quality degradation of a switching node in a packet forwarding network, characterized in that it performs an automatic protection switching operation according to

Images