KR101624621B1 - Method and apparatus for deciding dynamic label switched path in multi protocol label switching network - Google Patents

Abstract

The present invention relates to a method and apparatus for dynamically determining a backup protection path in a multi-protocol label switching network. Each node of the multi-protocol label switching network receives link information including link utilization rate and link reservation information of each link from other nodes of the multi-protocol label switching network, and based on the received link utilization rate and link reservation information, The backup protection path having no traffic loss on the transmission path is selected in advance and the node that has detected the link failure selects one of the prepared backup protection paths and determines the final backup protection path to bypass the traffic. When the final backup protection path can not be determined, the node that detects the link failure requests a dynamic backup protection path setting to the node one hop ahead in the direction of the traffic start, and the nodes one hop ahead likewise prepare the backup protection Select one of the routes to bypass the traffic. When the node can not determine the backup protection route for the one hop, the above procedure is repeatedly performed to the source node sequentially.

Description

METHOD AND APPARATUS FOR DECIDING DYNAMIC LABEL SWITCHED PATH IN MULTI PROTOCOL LABEL SWITCHING NETWORK FIELD OF THE INVENTION [0001]

The present invention relates to Multi Protocol Label Switching (MPLS) technology, and more particularly, to a method and apparatus for dynamically determining a backup protection path in a multi-protocol label switching network.

Multiprotocol Label Switching (MPLS) technology uses a second layer of switching technology such as ATM or Frame Relay to speed up packet forwarding based on existing routing schemes and to provide scalability of the network This is a kind of third layer switching technology that combines the routing function of the third layer and its characteristics can be roughly divided into three.

First, introduction of label switching concept enables fast packet transmission. Second, the concept of reservation is introduced by setting LSP (label switched path) before transmitting traffic. Third, CR-LSP: Constrained Route LSP), and explicit LSP (ER-LSP: Explicit route LSP). Therefore, multi-protocol label switching can make it easier to support functions that were previously difficult to support, such as traffic engineering, and can be used to improve the viability and reliability of Internet Protocol (IP) networks.

In order to provide reliable service in MPLS, it is important to allow traffic on the LSP to be transmitted while avoiding link errors or congestion. A solution to the problem is to establish a protection path .

The method of setting the protection path is divided into two basic models: reroute and protection switching.

A reroute is a method of establishing a protection path by signaling, and a new path is established by a traffic protection request after a failure occurs in a traffic transmission link or a node. This new path is based on fault information, network routing policy, or pre-defined configuration or network type information, and establishes a path that bypasses the failed path through signaling as soon as a fault is detected. Since the reroute scheme sets the protection route after the failure is detected, the route recovery time is inevitably slower than the protection switching scheme and the traffic loss can not be avoided.

1, the LSR 5, which detects a link failure when a link failure occurs between the LSR (Label Switching Router) 5 and the LSR 7 as shown in FIG. 1, LSR5-LSR7-LSR8-LSR8-LSR8-LSR8-LSR8-LSR8-LSR8-LSR8-LSR8-LSR8- LSR7-LSR8 path is selected as the protection path. However, if the bandwidth that the LSR6-LSR7-LSR8 path link can accommodate at this time is 100M, the traffic existing on the link is 70M, and if the traffic changed by the link failure in the LSR5 is 70M, the LSR6-LSR7- The traffic that flows is 140M total, which causes traffic loss of 40M beyond the capacity limit of 100M bandwidth.

However, as described with reference to FIG. 1, since a recovery path is set after a failure occurs, no resource is allocated until a failure occurs and a failure location is known. Therefore, .

On the other hand, protection switching is a method of establishing a protection path in advance based on the network's routing policy. Based on the routing policy of the network, it sets up the protection path in advance and reserves the resource, and if the failure occurs, it replaces the traffic with the protection path immediately. Therefore, although the protection switching method has a merit that it can perform path recovery faster than the reroute method, it can waste resources by reserving resources in advance and reduce the overall reliability of the network. These protection transitions include local recovery and end-to-end recovery.

Local restoration is to move traffic back to the source, that is, in the reverse direction, at the LSR that found the path failure. The LSR that finds the path failure returns traffic to the ingress LSR from which the traffic originated, and the ingress LSR reroutes the returned traffic to an alternate protection path that is set in advance.

End-to-end recovery is only to notify the LSR that it has detected a path failure, not a rerouting, but a failure notification message to the ingress LSR. When the LSR that finds the failure notifies the entrance LSR of the failure, the entrance LSR switches the newly arrived traffic to the alternative protection path that is set in advance, not the path where the failure occurred, based on the failure notification message.

This protection switching has advantages that it is possible to perform path recovery faster than the reroute method. However, as described above, there is a problem that resources are wasted by setting a protection path and reserving resources in advance.

2, when a failure occurs in the link between the LSR 5 and the LSR 7, the LSR 5, which detects a failure, notifies the traffic to the LSR 7, Lt; / RTI > Then, the entrance LSR1 sets the LSR2-LSR4-LSR6-LSR7-LSR8 path as the recovery path among the alternative protection paths set in advance by resource reservation, and bypasses the traffic. In this way, the entrance LSR1 sets up various protection paths in advance in case of a failure in the path of traffic transmission, and reserves resources. Therefore, resources (for example, bandwidth) other than reserved resources can not be used in the protection path, resulting in traffic loss. For example, in the above example, when the entrance LSR1 sets the LSR2-LSR4-LSR6-LSR7-LSR8 path as a protection path for traffic detour, if the reserved bandwidth of 70M is reserved but is not actually used as an alternative path for traffic detour, LSR2-LSR4-LSR6-LSR7-LSR8-LSR8-LSR8-LSR7-LSR8, the link can use only 30M in addition to the reserved 70M, resulting in a traffic loss of 40M in LSR2-LSR4-LSR6-LSR7-LSR8 .

3, when a failure occurs in a link between the LSR 5 and the LSR 7, the LSR 5, which detects a failure, transmits a Failure Notification message ). Then, the entrance LSR1 selects an LSR2-LSR4-LSR6-LSR7-LSR8 path among the preset protection paths as an alternative protection path, and forwards the incoming traffic from that point to the selected protection path. Therefore, traffic continues to be lost until the failure notification message is received from the LSR 5 at which the entrance LSR 1 finds a failure, and since the resource reservation is made for the protection route in advance, the same traffic loss There is a problem that occurs.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to solve the problem of traffic loss during the time of setting a protection path in a reroute scheme in a conventional multi-protocol label switching network, Determine the dynamic backup protection path to solve the problem of loss and wasted network resources caused by presetting the protection path in the protection switching method and the problem of loss of traffic in the protection path when new traffic occurs A method and an apparatus are provided.

Other objects and advantages of the present invention will become apparent from the following description, and it will be understood by those skilled in the art that the present invention is not limited thereto. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to an aspect of the present invention, there is provided a method for determining a dynamic backup protection path for a specific traffic transmission path in a multi-protocol label switching network, wherein each node of the multi- Receiving link information including link utilization rate and link reservation information of each link; Selecting a backup protection path in which each of the nodes has no traffic loss for the specific traffic transmission path based on the link utilization rate and link reservation information; Selecting one of the selected backup protection paths as a final backup protection path; And bypassing traffic to the determined final backup protection path by the node that has found the link failure.

If it is determined that the final backup protection path can not be determined in the step of determining the final backup protection path, the node detecting the link failure sends a backup protection path setup request message to the node one hop before the origin of the specific traffic transmission path The method comprising:

According to another aspect of the present invention, there is provided an apparatus for determining a dynamic backup protection path for a specific traffic transmission path in a specific node of a multi-protocol label switching network, A link information receiving unit that receives link information including link utilization rate and link reservation information of each link; A calculation unit for calculating a backup protection path having no traffic loss for the specific traffic transmission path based on the received link utilization rate and link reservation information; And determining a final backup protection path for selecting one of the calculated backup protection paths to bypass traffic when a link failure is detected.

The apparatus further includes a request transmission unit for transmitting a backup protection path setting request message to a node in the direction of the starting point on the specific traffic transmission path in response to the notification of the determination unit when the determination unit can not determine the final backup protection path, And a processing unit.

The present invention solves the conventional traffic loss problem by configuring a backup protection path in which a router detecting a failure of a transmission path does not cause traffic loss based on link utilization rate and link reservation information of other routers.

Further, the present invention is not limited to a resource reservation by setting a protection path in advance, but a traffic loss occurs immediately when a failure occurs in a transmission path in a state where a protection path is prepared dynamically based on link utilization rate and link reservation information It determines the protection path not to be used and bypasses the traffic so that the network resource can be efficiently used.

In addition, when a backup protection path can not be configured in a router that detects a failure of a transmission path, the present invention provides a backup protection path in a router immediately ahead of one hop to bypass traffic, thereby shortening the protection path setting time Thereby minimizing traffic loss.

FIG. 1 is a diagram for explaining a protection path setting method by a laughter scheme.
Figure 2 is a diagram illustrating local recovery during protection switching.
Figure 3 is a diagram illustrating end-to-end recovery during protection switching.
4 is a flowchart illustrating a method for determining a dynamic backup protection path in an MPLS network according to an exemplary embodiment of the present invention.
FIG. 5 is a diagram illustrating a process of determining a backup protection path and bypassing traffic according to an embodiment of the present invention. Referring to FIG.
6 is a diagram for explaining a process of determining a backup protection path and bypassing traffic according to another embodiment of the present invention.
7 is a diagram illustrating a configuration of a backup protection path determining apparatus for determining a dynamic backup protection path in an MPLS network according to an embodiment of the present invention.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: There will be. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the existing multiprotocol label switching (MPLS) network, it is inevitable to waste the network resources and lose the traffic. In order to solve this problem, not only the shortest path label switching considering only a metric but also the link utilization rate actually used in each link and the Constrained Route-Label Distribution Protocol (CRP-LDP) in a multi-protocol label switching (MPLS) Each LSR prepares a dynamic backup LSP in advance to prepare a dynamic backup LSP based on this information. Then, when a failure occurs, the LSR can delay the traffic without delay So that no loss of traffic occurs.

4 is a flowchart illustrating a method for determining a dynamic backup protection path in a multi-protocol label switching network according to an exemplary embodiment of the present invention.

As shown in FIG. 4, each router of the multi-protocol label switching network firstly notifies the link bandwidth and the number of hops as well as the link utilization rate and the link reservation information reserved by the CR-LDP to other routers by the routing protocol (S401 ). In the present Open Shortest Path First (OSPF), the metric is transmitted to link-state-advertisement (LSA) so that each network node can share a metric calculated in consideration of link bandwidth and hop count, Are being routed.

In the meantime, the multi-protocol label switching technology defines a variety of Opaque-LSA OSPF extensions. The Opaque LSA defines 32-bit application-specific information fields as shown in Table 1 below. Only the principle of using and passing this information between network nodes is specified [RFC 5250]. Therefore, each LSR inputs the link utilization rate not used in the existing OSPF and the reservation information of each link reserved by the CR-LDP as data of the Opaque Information field of the Opaque LSA shown in [Table 1] Share.

In this way, each router of the multi-protocol label switching network receives and stores link utilization rate and link reservation information from neighboring routers, and then, based on the link utilization rate and reservation information of each received link, The backup protection path is set in advance (S403). In this case, it means that the various protection paths without traffic loss are simply calculated and prepared based on the link utilization rate and link reservation information of each link instead of reserving the link on the backup protection path in practice. Thus, there can be one or more backup protection paths without traffic loss.

When the link utilization rate and the link reservation information of the link managed by the routers are changed, each router changes the link utilization rate and the link reservation information as Opaque LSA Opaque Information field to the other routers (S401), and each router continuously updates the preset backup protection path based on the changed link usage rate and link reservation information (S403). Preferably, each LSR can propagate the Opaque LSA whenever the link utilization and link reservation information is updated, or periodically propagate link utilization and link reservation information.

That is, when a backup protection path prepared in advance based on the link usage rate and link reservation information of each link received previously is checked based on the link utilization rate and link reservation information of each link received thereafter, traffic loss occurs Routers, each router continually updates its backup protection path whenever it receives link utilization and link reservation information for each link from other routers. Therefore, if the path previously set as the backup protection path does not cause any traffic loss, and the traffic loss occurs according to the link use or link reservation after that, the corresponding protection path is removed from the backup protection path.

When a failure occurs in a specific link or router (S405) in a state where each router has preset a backup protection path for a specific traffic path, the router that finds the failure may perform the backup protection It is checked whether the path remains (S407). Since the backup protection path is continuously updated through the steps S401 and S403, the router that has found the failure checks whether there is a remaining backup protection path that has not been removed. Since each router receives and stores the link utilization rate and reservation information of each link as described above, the router that has found the failure finally obtains the traffic loss May occur.

As a result of the check, if there is a backup protection path that does not cause a traffic loss, the router that has found the failure determines one of the remaining backup protection paths as the final protection path, preferably the backup path of the shortest path to the destination (S409). In step S411, the router that has detected the failure bypasses the traffic with the determined final protection path as an alternative path.

On the other hand, if it is determined in step S407 that there is no remaining backup protection path, that is, if traffic loss occurs in all the backup protection paths and the router is removed, the router that has found the failure does not determine an alternative path, And transmits a dynamic LSP setup request message to the router located in the front (S413).

Upon receiving the dynamic LSP setup request message, the router located one hop before the departure direction checks whether there is a backup protection route prepared in advance based on the link utilization rate and link reservation information of each link received from another router (S415).

As a result of the checking in step S415, if there is a backup protection path that does not cause a traffic loss, the router located in front of the one-hop destination has one of the remaining backup protection paths, preferably the backup protection path of the shortest path to the destination (S417), and bypasses the traffic using the determined final backup protection path as an alternative path (S419). Then, the router transmits a dynamic LSP setup response message to the router that has found the failure, and notifies the router that the protection path setup is completed (S421)

However, if it is determined in step S415 that there is no backup protection path that does not cause traffic loss, that is, if a traffic loss occurs in all the backup protection paths, then, from the router located in front of the one hop to the entry router, The above-described operations S413 to S421 are repeated until a protection path that does not cause traffic loss is found among backup protection paths set in advance.

According to the present invention, each LSR dynamically prepares a backup backup path (dynamic backup LSP) in advance based on the link utilization rate and link reservation information of each link, and when a failure occurs, Do not occur. Also, traffic loss is minimized by bypassing traffic by searching for backup protection paths that have no traffic loss sequentially from the LSR that found the failure to the entrance LSR.

A specific example will be described below with reference to Figs. 5 and 6. Fig.

FIG. 5 is a diagram illustrating a process of determining a backup protection path and bypassing traffic according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 5, when traffic is generated in the ingress LSR1 and traffic is transmitted to the path of LSR3-LSR5-LSR7-LSR8, the LSR5 generates LSR5-LSR6-LSR7-LSR8 as a backup- , LSR5-LSR9-LSR10-LSR8, LSR5-LSR9-LSR10-LSR7-LSR8 can be selected in advance. That is, the LSR 5 selects the three paths as the backup protection path as a protection path without traffic loss based on the link utilization rate and link reservation information propagated from other routers. When a failure occurs in the link between the LSR 5 and the LSR 7, the LSR 5 that finds the failure determines the path of the shortest distance among the above three paths as the final backup protection path and bypasses the traffic.

When new traffic 70M is transmitted or a specific bandwidth is reserved for the path of the LSR6-LSR7-LSR8 among the above three paths before a failure occurs in the link between LSR5 and LSR7, each LSR LSR5-LSR6-LSR7-LSR8 of the three backup protection paths based on the propagated received Opaque LSA, and the LSR5 propagates LSR6 -LSR7 and LSR7-LSR8 traffic loss occurs, and in case of LSR5-LSR9-LSR10-LSR7-LSR8, it is confirmed that traffic loss occurs in LSR7-LSR8. LSR5 selects LSR5-LSR9-LSR10-LSR8 excluding the two paths among the three backup protection paths in advance as a backup protection path, and if a failure occurs in the link between LSR5 and LSR7, LSR9-LSR10-LSR8 path is determined as the final backup protection path, and the traffic is bypassed to transmit the traffic without loss.

6 is a diagram for explaining a process of determining a backup protection path and bypassing traffic according to another embodiment of the present invention.

Referring to FIG. 6, in the process of traffic being generated in the ingress LSR1 and traffic is transmitted to the path of LSR3-LSR5-LSR7-LSR8, the LSR5 generates LSR5-LSR6-LSR7-LSR7 as a backup- Three paths of LSR8, LSR5-LSR9-LSR10-LSR8 and LSR5-LSR9-LSR10-LSR7-LSR8 can be selected in advance. At this time, when new traffic is transmitted to the path of LSR2-LSR4-LSR6-LSR7-LSR8 or a specific bandwidth is reserved, each router spreads its link utilization rate and link reservation information to Opaque LSA to share. Therefore, LSR5 confirms that traffic loss occurs in LSR6-LSR7-LSR8 path based on the propagated received Opaque LSA, and LSR5 can no longer secure backup protection path for traffic loss protection.

In this situation, if a failure occurs between the link between LSR5 and LSR7 and the link between LSR5 and LSR9, the LSR5 that finds the failure does not have a pre-selected backup path to the pre-dynamic backup LSP, Since the dynamic backup protection path can not be set, a dynamic LSP setup request message is transmitted to the LSR 3 in front of one hop. The LSR 3 that has received the dynamic backup protection path setup request message determines LSR3-LSR9-LSR10-LSR8, which is a backup protection path (pre-dynamic LSP) having no preset traffic loss as a final backup protection path, To bypass traffic.

Then, the LSR 3 sends a dynamic backup protection path setup response message to the LSR 5 which has transmitted the dynamic backup protection path setup request message, so that the LSR 5 does not need to generate the dynamic backup protection path setup request message any more It informs.

7 is a block diagram of a backup protection path determining apparatus for determining a dynamic backup protection path in a multi-protocol label switching network according to an embodiment of the present invention.

7, the backup protection path setting apparatus includes a link information detection unit 710, a link information transmission unit 720, a link information reception unit 730, a backup protection path calculation unit 740, a link failure detection unit 730, 750, a backup protection path determination unit 760, a backup protection path setup request transmission processing unit 770, and a backup protection path setup request reception processing unit 780.

The link information detection unit 710 detects the link bandwidth, link utilization rate, and link reservation information managed by the router equipped with the backup protection path setting apparatus.

The link information transmission unit 720 propagates link information such as bandwidth, link utilization rate, link reservation information, and the like detected by the link information detection unit 710 to each router of the multi-protocol label switching network. Information such as the link bandwidth or the number of hops is propagated through link-state-advertisement (LSA), and the link utilization rate and link reservation information are propagated through Opaque information of the Opaque LSA.

The link information receiving unit 730 receives the link information propagated from the backup protection path determining apparatus mounted on another router. As described above, information such as the link bandwidth and the number of hops is propagated through the LSA, and the link utilization rate and the link reservation information are propagated through the Opaque information of the Opaque LSA.

The backup protection path calculating unit 740 calculates a backup protection path in which no traffic loss occurs for specific traffic transmission paths by using the link utilization rate and link reservation information of each link in the link information receiver 730 . The backup protection path calculating unit 740 does not perform the resource reservation for the backup protection path but merely calculates and selects as many backup protection paths as possible for the transmission path of the specific traffic.

When the link utilization rate and the link reservation information of each link are received from the link information receiver 730, the backup protection path calculator 740 uses the information for each time the information is received, The backup protection path that does not cause a traffic loss is re-calculated, and the backup protection path that has been previously calculated is updated.

The link failure detection unit 750 detects a failure of the link (or a failure of the router) connected to the router on which the backup protection path determination apparatus is mounted, and detects a failure of the link, etc., And notify the relevant facts.

When the backup protection path determining unit 760 is notified of the failure of the specific link from the link failure detecting unit 750, the backup protection path determining unit 760 finally determines the backup protection path of the traffic transmission path using the failed link.

Specifically, the backup protection path determining unit 760 determines the backup path of the shortest path among the plurality of backup protection paths previously calculated and selected by the backup protection path calculating unit 740 for the traffic transmission path using the failed link, The protection path is determined as the final backup protection path. If there is only one backup protection path remaining, the remaining path is determined as the final backup protection path. When the backup protection path determining unit 760 determines the final backup protection path, the router equipped with the backup protection path determining apparatus bypasses the traffic through the determined backup protection path.

Meanwhile, the backup protection path determination unit 760 determines whether or not there is a backup protection path bypassing the failed link, that is, the backup protection path 740, which is calculated as a path in which traffic loss does not occur in the backup protection path calculation unit 740, The backup protection route determining unit 760 notifies the backup protection route setting request transmission processing unit 770 of the relevant information. At this time, the backup protection path determination unit 760 transmits information such as a traffic transmission path to the backup protection path establishment request transmission processing unit 770.

The backup protection path setup request transmission processing unit 770 notifies the router in the hop direction one hop ahead of the origin of the traffic transmission path using the failed link according to the notification of the backup protection path determination unit 760, Message. The dynamic backup protection path setup request message includes information on a traffic transmission path.

The backup protection path setup request transmission processing unit 770 receives the dynamic backup protection path setup response message from the router in the hop direction one hop after the backup protection path is finally determined and the traffic is bypassed Thereby confirming that traffic is being bypassed without loss of traffic.

On the other hand, the backup protection path setup request reception processing unit 780 receives the dynamic backup protection path setup request message transmitted from another router, and transmits information about the traffic transmission path included in the received dynamic backup protection path setup request message And transmits it to the backup protection path determination unit 760.

When the backup protection path determination unit 760 determines the final traffic protection path, the backup protection path setup request reception processing unit 780 sets the backup protection path to another router that has transmitted the dynamic backup protection path setup request message Response message to inform the other router that the traffic is being diverted to the backup protection path.

The backup protection path determination unit 760 determines a backup protection path based on the information transmitted from the backup protection path setup request reception processing unit 780 by referring to the backup protection path 740, The backup protection path of the shortest distance is determined as the final backup protection path. When the backup protection path determining unit 760 determines the final backup protection path, the router equipped with the backup protection path determining apparatus bypasses the traffic through the determined backup protection path.

At this time, when there is no backup protection path that is calculated and prepared in advance and a traffic loss occurs in all the backup protection paths, the backup protection path determination unit 760 notifies the backup protection path setting request transmission processing unit 770 of the relevant fact, The backup protection path setup request transmission processing unit 770 transmits a dynamic backup protection path setup request message requesting a router in the hop direction one hop in the departure direction on the corresponding traffic transmission path to set a backup protection path for the corresponding traffic transmission path.

The method of the present invention as described above may be embodied as a program and stored in a computer-readable recording medium (such as a CD-ROM, a RAM, a ROM, a floppy disk, a hard disk, or a magneto-optical disk).

While the specification contains many features, such features should not be construed as limiting the scope of the invention or the scope of the claims. In addition, the features described in the individual embodiments herein may be combined and implemented in a single embodiment. Conversely, various features described herein in a single embodiment may be implemented in various embodiments individually or in a suitable subcombination.

It is to be understood that, although the operations have been described in a particular order in the figures, it should be understood that such operations are performed in a particular order as shown, or that a series of sequential orders, or all described operations, . In some circumstances, multitasking and parallel processing may be advantageous. It should also be understood that the division of various system components in the above embodiments does not require such distinction in all embodiments. The above-described program components and systems can generally be implemented as a single software product or as a package in multiple software products.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings.

710: Link information detecting unit 720: Link information transmitting unit
730: Link information receiving unit 740: Backup protection path calculating unit
750: Link failure detection unit 760: Backup protection path determination unit
770: Backup protection path setting request transmission processing section
780: Backup protection path setup request reception processing unit

Claims (12)

A method for determining a dynamic backup protection path for a specific traffic transmission path in a multi-protocol label switching network,
(A) receiving, by each node of the multiprotocol label switching network, link information including link utilization rate and link reservation information of each link from other nodes;
(B) selecting, by the nodes, a backup protection path having no traffic loss for the specific traffic transmission path based on the link utilization rate and the link reservation information;
(C) a node that has detected a link failure selects one of the selected backup protection paths as a final backup protection path;
(D) bypassing traffic to the determined final backup protection path by a node that has detected the link failure; And
(E) If the final backup protection path can not be determined in the step (C), the node detecting the link failure sends a backup protection path setup request message to the node in the direction of the starting point on the specific traffic transmission path, The method comprising the steps of: delete The method according to claim 1,
(F) determining, as a final backup protection path, one of the backup protection paths selected in the step (B) according to the reception of the backup protection path setting request message by the node in the previous hop; And
(G) bypassing traffic to the last backup protection path determined in step (F) by a node ahead of the one hop. The method of claim 3,
If it is determined in step (F) that the next hop of the next hop can not determine the final backup protection path,
Wherein a backup protection path establishment request message is sequentially transmitted from a node before the one hop to a source node of the specific traffic transmission path until a backup protection path without traffic loss is determined. 5. The method of claim 4,
Receiving a backup protection path establishment response message informing that the node that has detected the link failure has completed the backup protection path determination from the node that has determined the final backup protection path for the specific traffic transmission path, How to determine the protection path. 6. The method according to any one of claims 1 to 5,
The link utilization rate and the link reservation information are used,
And recorded in an Opaque Information field of an Opaque link-state-advertisement (LSA) and propagated. An apparatus for determining a dynamic backup protection path for a specific traffic transmission path at a specific node of a multi-protocol label switching network,
A link information receiving unit for receiving link information including link utilization rate and link reservation information of each link from other nodes of the multi-protocol label switching network;
A calculation unit for calculating a backup protection path having no traffic loss for the specific traffic transmission path based on the received link utilization rate and link reservation information;
When the link failure is detected, selecting one of the calculated backup protection paths to determine a final backup protection path to bypass the traffic; And
And a request transmission processing unit for transmitting a backup protection path establishment request message to a node in the starting direction on the specific traffic transmission path in response to the notification of the determination unit when the determination unit can not determine the final backup protection path A device for determining a dynamic backup protection path. delete 8. The method of claim 7,
The request transmission processing unit,
And when the backup protection path determination is completed from the node in front of the one hop, receiving a backup protection path setup response message as a response to the backup protection path setup request message. 10. The method according to claim 7 or 9,
Further comprising: a request reception processor for receiving a backup protection path establishment request message for the specific traffic transmission path from another node,
Wherein the determination unit determines a final backup protection path that selects one of the backup protection paths calculated by the calculation unit and bypasses the traffic when the request reception processing unit receives the backup protection path setting request message. Protection path determining device. 11. The method of claim 10,
The request reception processing unit,
Wherein when the final backup protection path is determined by the determination unit, a backup protection path establishment response message is transmitted to another node that has transmitted the backup protection path setup request message. 10. The method according to claim 7 or 9,
The link utilization rate and the link reservation information are used,
And recorded in an Opaque Information field of an Opaque link-state-advertisement (LSA).

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