KR100273769B1 - Restoration method for virtual path connection of atm network - Google Patents

Abstract

The present invention relates to a method for recovering a virtual path connection in an asynchronous transmission mode communication network which is configured to handle recovery of a predetermined virtual path connection quickly in case of a failure in the asynchronous transmission mode communication network. When a connection is created and data is transmitted / received through the primary connection, when a failure occurs in the primary connection, it is quickly switched to a spare connection to ensure the failover of the virtual path connection in the asynchronous transmission mode network. It is applied to the network management system of the communication network and is executed in real time and dynamically by the organic relationship of the information objects defined in the network management system to ensure fast and reliable connection recovery for the virtual path connection of the important asynchronous transmission mode requiring reliability. Done.

Description

Virtual Path Connection Recovery Method in Asynchronous Transmission Mode Network

The present invention relates to a method for recovering a virtual path connection in an asynchronous transmission mode communication network, and more particularly, to a method for recovering a virtual path connection in an asynchronous transmission mode communication network applied to a network management system to provide a highly reliable virtual path connection service. It is about.

In ITU-T G.805, which has recently proposed a hierarchical network structure, a large public telecommunications network is based on the transmission characteristics of the synchronous digital hierarchy (SDH), asynchronous transfer mode (Asynchronous Transfer Mode) It is composed of one or more hierarchical networks such as Virtual Path (VP) and Virtual Channel (VC). One virtual path connection (VPC) may include a plurality of virtual channel connections (VCC). The reliability of the virtual path connection has a great influence on the reliability of the virtual channel connection included in the virtual path connection, and its ripple effect is also very large.

Therefore, it is very important to ensure the connection recovery in the shortest time in the event of a failure of the virtual path connection.

Accordingly, the present invention has been made in view of the above-described conventional situation, and an object of the present invention is to provide a method for recovering a virtual path connection in an asynchronous transmission mode communication network, which is configured to quickly recover a predetermined virtual path connection when a failure occurs in the asynchronous transmission mode communication network. There is this.

In order to achieve the above object, the virtual path connection recovery method in the asynchronous transmission mode communication network according to the preferred embodiment of the present invention is a normal path for a connection requiring the best reliability according to the virtual path connection service level of the asynchronous transmission mode. Simultaneously creating a primary virtual path connection for transmitting / receiving data and a preliminary virtual path connection in preparation for a failure of the primary virtual path connection;

And when a failure occurs in the connection of the primary virtual path when data is transmitted / received by the primary virtual path connection, a process of switching to the preliminary virtual path connection.

1 is a physical configuration diagram of an asynchronous transmission mode communication network applied to the present invention,

FIG. 2 is a view for explaining the hierarchical structure of the virtual path layer network of the asynchronous transmission mode communication network shown in FIG. 1; FIG.

3 is a view illustrating a shape of a virtual path connection setting of the asynchronous transmission mode communication network shown in FIG. 1;

4 is a configuration diagram of a hierarchical network and a partial network manager employed in the present invention;

FIG. 5 is a diagram illustrating a flow of virtual path connection establishment in the hierarchical network and subnetwork manager configuration shown in FIG. 4; FIG.

6 is a view showing a correlation between connection information objects after establishing a virtual path connection in the present invention;

7 is a flow diagram of switching when a failure occurs according to an embodiment of the present invention;

8 is a view showing a switching shape of the switch level according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: hierarchical network manager

12, 18, 26, 34, 41, 48: Configuration Management Subsystem

14, 20, 28, 36, 42, 50: connection management subsystem

15, 22, 30, 37, 44, 52: database

16, 24, 32: network manager subnetwork manager

38, 39, 40, 45, 46, 47: element manager layer network manager

54-64, 116, 117: Asynchronous transfer mode switch

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

1 is a physical configuration diagram of an asynchronous transmission mode communication network according to the present invention, and is composed of a link connecting an asynchronous transmission mode switch (ATM SW), a port, and an asynchronous transmission mode switch (ATM SW). In FIG. 1, the physical shape management areas 100 and 101 of two asynchronous transmission mode communication networks including an asynchronous transmission mode switch, a port, and a link are set, respectively, to show a connection relationship therebetween.

A hierarchical network structure in which an asynchronous transmission mode virtual path layer network is divided into partial networks according to ITU-T G.805 based on the physical shape of the asynchronous transmission mode communication network shown in FIG. 1 may be represented as shown in FIG. In addition, the asynchronous transmission mode virtual path layer network is divided into one or more subnetworks (SNWs) according to a management domain or a local network concept, and any divided subnetwork is further divided into one or more subnetworks. This partitioning continues until the subnetwork corresponds 1: 1 with the asynchronous transfer mode switch (ATM SW).

The asynchronous transmission mode virtual path layer network is defined as the following hierarchical structure. Subnetwork segmentation for the asynchronous transmission mode virtual path layer network belongs to a subnetwork belonging to a network management layer (NML) defined by an ITU-T Telecommunication Management Network (TMN) (hereinafter, nmlSNW _i ). And the subnetwork belonging to the element management layer (EML) (hereinafter, emlSNW _i ). Sub-networks that correspond to asynchronous transfer mode switches or cross connectors in a 1: 1 fashion are defined as element management layer sub-networks (emlSNW), and sub-networks containing one or more sub-networks are defined as network management layer sub-networks (nmlSNW). . There are a number of link termination points (LTP: Link Termination Points (LTP _ijk )) corresponding to the ports of the asynchronous transfer mode switch in the subnetwork, and the links between neighboring switch ports are the phase links between the link endpoints of the subnetwork. , TL _i ).

In FIG. 1, the asynchronous transfer mode switch ATM SW _1.1 corresponds to the element management layer subnetwork emlSNW _1.1 of FIG. 2, and the asynchronous transfer mode switch ATM SW _1.2 , ATM SW _1.3 , ATM SW _2.1 , ATM SW _2.2. , ATM SW _2.3 ) corresponds to the element management layer subnetwork (emlSNW _1.2 , emlSNW _1.3 , emlSNW _2.1 , emlSNW _2.2 , emlSNW _2.3 ), respectively.

At least one port exists in the asynchronous transfer mode switch (ATM SW _1.2 , to ATM SW _2.3 ), which is represented by a link endpoint (LTP) in FIG. 2. The port (port _1.1.1 ) of the asynchronous transfer mode switch (ATM SW _1.1 ) of FIG. 1 is represented by the link endpoint LTP _1.1.1 of the element management layer subnetwork emlSNW _1.1 of FIG. 2, which is also network management. It is represented by different link endpoints (LTP) in the layer subnetwork and the layer network, but represents the same port (port _1.1.1 ) of the asynchronous transfer mode switch (ATM SW _1.1 ).

Links connecting arbitrary ports included in the asynchronous transfer mode switch are not represented in the network element management layer but are represented as part of the configuration information in the network management layer subnetwork. The shape information is used for routing by expressing a shape in which a subnetwork SNW, a link endpoint LTP included in the subnetwork, and a link endpoint of a neighbor subnetwork are connected by a phase link TL. That is, since the asynchronous transfer mode switches (ATM SW _1.1 , ATM SW _1.2 , ATM SW _1.3 ) of FIG. 1 are defined as one network management layer subnetwork, these asynchronous transfer mode switches (ATM SW) are illustrated in FIG. 2. Each of them is represented by the element management layer subnetwork (emlSNW), and in the network management layer subnetwork (nmlSNW ₁ ), the segmentation of the configuration information (emmlSNW ₁ of FIG. 2) between the element management layer subnetwork (emlSNW). Shape). In addition, the phase link TL ₁ of the segment shape information maintained by the network management layer subnetwork nmlSNW ₁ of FIG. 2 is a link ₁ connecting the asynchronous transmission mode switch ATM SW _1.1 and ATM SW _{1.2 of} FIG. _1. The phase link TL ₂ represents link ₂ connecting the asynchronous transfer mode switches ATM SW _1.1 and ATM SW ₁ , _{3 of} FIG. 1. Links ₄ and ₅ of FIG. 1 are included in the shape segmentation information of the network management layer subnetwork nmlSNW ₀ in FIG. 2. This is in accordance with the above-described layering and segmentation concept of ITU-T G.805. In the segmentation information of the network management layer subnetwork (nmlSNW ₀ ), the element management layer subnetwork is not visible and the network management layer subnetwork is not shown. (nmlSNW ₁ and nmlSNW ₂ ) and only the phase links (TL ₅ , TL ₆ ) connections between them can be seen.

In order to establish a virtual path connection (VPC) on the hierarchical structure of the virtual path hierarchy network of the asynchronous transmission mode defined in FIG. 2, connection expression information objects as shown in FIG. 3 are defined.

A connection between any link endpoints in a virtual path layer network in asynchronous transmission mode is called a trail. This trail represents the end-to-end connection without dealing with the details of the virtual path connections (routing paths, etc.) at the highest level, where the trail connection ends at the trail termination point (TTP) within the link termination. Create a and bind it to the trail to represent the connection. The trail endpoint (TTP) is assigned a virtual path identifier (VPI).

In FIG. 3, an internal connection between any link endpoints present in the subnetwork is called a subnetwork connection (SNC), and in particular, a connection inside the element management layer subnetwork (emlSNW) is referred to as an element management layer subnetwork connection (SNC). emlSNC _i ), and the connection inside the network management layer subnetwork (nmlSNW) is called a network management layer subnetwork connection (nmlSNC _i ). In order to create the element management layer subnetwork connection (emlSNC _i ) and the network management layer subnetwork connection (nmlSNC _i ), a connection termination point (CTP) is created at a link endpoint (LPT) belonging to each subnetwork. It binds the subnetwork connection. In addition, a link link (LC) is created in the phase link (TL) connecting the sub-networks, and these are bound to the connection endpoint (CTP) generated when the sub-network connection is generated to express the end-to-end connectivity as a whole.

As shown in FIG. 3, the main connection between the ATM VP LNW of the asynchronous transmission mode is composed of a main trail and trail endpoints TTP _1.1 and TTP _2.1 . The connection within the network management layer subnetwork 0 (nmlSNW ₀ ) consists of the network management layer subnetwork connection (nmlSNC ₀ ) and its connection endpoints (CTP _1.1 and CTP _2.1 ). The connections within the network management layer subnetwork managers (nmlSNW ₁ and nmlSNW ₂ ) are the network management layer subnetwork connections (nmlSNC ₁ ) and their endpoints (CTP _1.1.1 and CTP _1.2.1 ) and network management layer parts, respectively. It consists of a network connection (nmlSNC ₂ ) and its connection endpoints (CTP _2.1.1 and CTP _2.3.1 ).

Thus, the inner connection of network management layer subnet connection of the network management layer subnets (nmlSNW ₀₎ (nmlSNC ₀₎ is a network management layer subnet connection of a lower level (nmlSNC _1), link connection (LC _5.1) and a network management layer It consists of a subnetwork connection (nnmlSNC ₂ ). The connection to the element management layer subnetwork (emlSNW) is also created by the same process as above.

In FIG. 3, a node where a transmitting / receiving point used for establishing an asynchronous transmission mode virtual path connection is located is called an access node. In FIG. 3, a link is established when establishing a connection between link endpoints (LTP _1.1.1 and LTP _2.3.2 ). The element management layer subnetwork (emlSNW _1.1 ) containing the endpoint (LTP _1.1.1 ) and the element management layer subnetwork (emlSNW _2.3 ) including the link endpoint (LTP _2.3.2 ) are called the access emlSNW. And asynchronous transfer mode switches (ATM SW _1.1 and ATM SW _2.3 ) of FIG. 1 corresponding to each of the access nodes.

Accordingly, the main connection and the preliminary connection settings made in the present invention are shown in FIG. 4 as layer network manager (LNWM), network management layer subnetwork manager (NSM ₀ , NMS ₁ , NMS ₂ ) and access element management layer subnetwork (emlSNW). _1.1 , emlSNW _2.3 ), except for the element manager layer network manager (ESM _1.1 , ESM _2.3 ), which is managed by ESM _1.2 , ESM _1.3 , ESM _2.1 , ESM _2.2 .

The access element management layer sub-network manager (ESM _1.1 , ESM _2.3 ) is connected to the element management layer sub-network (emlSNW _1.1 ) as the main element management layer sub-network (Main emlSNC _1.1 ) and the preliminary element management layer sub-network connection generate (Backup emlSNC _1.1), and generates the element management layer subnets (emlSNW _2.3) main element management layer subnet connection (main emlSNC _2.3) and spare element management layer subnet connection (Backup emlSNC _2.3) on, but the main components The connection establishment request for the asynchronous transmission mode switch is made only for the management layer subnetwork connection (Main emlSNC), and the switching request for the backup emlSNC is not requested. Therefore, at the switch level, data can be transmitted and received only through the primary virtual path connection, and data cannot be transmitted and received through the preliminary virtual path connection. In this situation, if any part of the primary connection fails, it is requested to delete the switch-level connection corresponding to the primary subnetwork connection (primary emlSNC _1.1 , primary emlSNC _2.3 ) established in the access network management layer subnetwork. When is completed, the switch is requested to switch the spare subnetwork connection (preliminary emlSNC _1.1 , spare emlSNC _2.3 ), so that data transmission and reception is performed through the preliminary virtual path connection.

FIG. 4 is a diagram illustrating the configuration of a virtual path hierarchy structure of the asynchronous transmission mode defined in FIG. 2 and the configuration of each layer network and subnetwork manager for performing a function of establishing and releasing a connection of a virtual path based on the same. A network manager (LNWM) and a subnetwork manager (SM) are provided.

Here, the SM is a network management layer subnetwork manager (NSM) (16, 24, 32), and an element management layer subnetwork manager (ESM); 38, 39 , LNWM; 10 manages virtual path layer networks and layer network endpoints in asynchronous transmission mode, creates trail connections between endpoints, and connects them. To determine the end-to-end location, select the NSM or NSM required for establishing a connection between them, and send a request for establishing a subnetwork connection. And, the layer network manager (LNWM) 10 is allocated to the asynchronous transmission mode virtual path layer network one by one.

The network management layer subnetwork manager 16 divides the network management layer subnetwork nmlSNW ₀ into a partitioned shape, and the network management layer subnetwork manager 24 divides the network management layer subnetwork nmlSNW ₁ into a split shape. The management layer subnetwork manager 32 manages the segmentation of the network management layer subnetwork nmlSNW ₂ , and each network management layer subnetwork manager 16, 24, and 32 has a routing function based on each segmentation. It also has a management function to create and delete network management layer subnetwork connections (nmlSNC) inside each subnetwork.

The element manager layer network managers 38, 39, 40, 45, 46, and 47 manage the link endpoints (LTPs) of the element management layer subnetwork (emlSNW), respectively. Provides the ability to create and delete management layer sub-network connections (emlSNC) to control connections one-to-one asynchronous transfer mode switches 54-64 so that connections are made at the switch level.

The layer network manager (LNWM) generates an asynchronous transmission mode virtual path layer network (ATM VP LNW) and link endpoints (LTP ₁ and LTP ₂ ) belonging to the configuration management subsystem (TMSS); And the creation, deletion, and modification of virtual path connections (primary and spare trails) on the asynchronous transport mode virtual path layer network (ATM VP LNW) created and maintained by the configuration management subsystem 12. A connection management subsystem (CMSS) 14 and an internal database (DB) 15 for storing information objects created by the configuration management subsystem 12 and the connection management subsystem 14.

The network management layer subnetwork managers (16; 24; 32) may include endpoint information (LTPs) of respective network management layer subnetworks (nmlSNW ₀ , nmlSNW ₁ , nmlSNW ₂ ; see FIG. 2) and respective internal shape information (FIG. A configuration management subsystem 18 (26; 34) for managing the divided shape of nmlSNW _0, the divided shape of nmlSNW _{1, and} the divided shape of nmlSNW ₂ defined in ₂ ; and each of the shape management subsystems (18; 26; 34). A connection management subsystem that provides the ability to create, delete, and modify network management layer subnetwork connections (primary and spare network management layer subnetwork connections) and link connections (primary and spare link connections) that are created and maintained. 28, 36, and to an internal database 22; 30; 37 for storing information objects created by the configuration management subsystems 18; 26; 34 and the connection management subsystems 20; 28; 36. It is composed.

Each element manager layer network manager 38; 39; 40; 45; 46; 47 is assigned to each element manager layer network emlSNW _1.1 ; emlSNW _1.2 ; emlSNW _1.3 ; emlSNW _2.1 ; emlSNW _2.2 ; emlSNW _2.3. ) And its endpoint information (LTPs) and the configuration management subsystem (TMSS _1.1 (41); TMSS _1.2 ; TMSS _1.3 ; TMSS _2.1 ; TMSS) that maintains and manages the relationship between these information objects and the switches and ports of asynchronous transfer mode switches. _2.2 ; TMSS _2.3 (48)), and the element management layer subnetwork created and maintained by the configuration management subsystem (TMSS _1.1 (41); TMSS _1.2 ; TMSS _1.3 ; TMSS _2.1 ; TMSS _2.2 ; TMSS _2.3 (48)). Provides the ability to create, delete, and modify connections (primary and spare element management layer subnetwork connections), and if the created element management layer subnetwork connection (emlSNC) is to the edge subnetwork, For a connection (emlSNC), a connection establishment request is sent to the switch, and a spare element management layer subnetwork connection (emlSNC) is sent. Connection management subsystem (CMSS _1.1 (42); CMSS _1.2 ; CMSS _1.3 ; CMSS _2.1 ; CMSS _2.2 ; CMSS _2.3 (50)) that provides the ability not to send a connection establishment request to the switch. _1.1 (41); TMSS _1.2 ; TMSS _1.3 ; TMSS _2.1 ; TMSS _2.2 ; TMSS _2.3 (48)) and Connection Management Subsystem (CMSS _1.1 (42); CMSS _1.2 ; CMSS _1.3 ; CMSS _2.1 ; CMSS _2.2 ; CMSS _2.3 ( 50)) consists of internal databases (DB _1.1 , DB _1.2 , DB _1.3 (44) _, DB _2.1 , DB _2.2 , DB _2.3 (52)) for storing the created information objects.

The asynchronous transfer mode switches ATM SW _1.1 , ATM SW _1.2 , ATM SW _1.2 , ATM SW _2.1 , ATM SW _2.2 , and ATM SW _2.3 ; 54 to 64 are element management layer subnetwork managers 38, 39, 40,. 45, 46, and 47) to enable the switch-level cell (data) to be transmitted from the switch through the switch-level connection setting, and to receive the disconnection request and to disconnect the switch-level connection. .

That is, all the information elements (VP LNW, nmlSNW, emlSNW, TL, LTP) representing the division of the virtual path layer network in the asynchronous transmission mode defined in FIG. 2 and the connection inside the virtual path layer network defined in FIG. Trail, TTP), connections within the network management layer subnetwork (nmlSNC, LC, CTP) and all information elements representing connections inside the element management layer subnetwork (emlSNC, CTP) are interconnected to the client / server on the distributed platform. Realized as objects that can act, the creation, deletion and management of these objects is made by the configuration management subsystem (TMSS) and connection management subsystem (CMSS) of each manager as defined in FIG.

Next, the virtual path connection recovery operation in the asynchronous transmission mode communication network according to an embodiment of the present invention will be described.

The present invention is largely divided into a process of establishing a main connection and a preliminary connection, and a process of switching to a preliminary connection when a failure occurs in the main connection.

First, a process of establishing a primary connection and a preliminary connection will be described with reference to the virtual path connection setting flowchart illustrated in FIG. 5.

First, the hierarchical network manager (LNWM) 16 receives a request for establishing a connection between a transmission / reception point (LTP _1.1.1 / LTP _2.3.2 ) designated by a user and simultaneously generates a main trail and a preliminary trail as shown in FIG. 6. Once the main and preliminary trails have been created, a relationship can be established between them to determine which preliminary trail is for the main trail.

Secondly, the layer network manager (LNMW) 10 which has created the main trail and the reserve trail and established the relationship between them is the network management layer sub-network manager (NSM ₀ ; 16) under the virtual path layer network manager 10. Request to create network management subnetwork connection.

Third, the network receives the network management layer subnet connection request management layer subnet manager 16 link end point (LTP _1.1 as shown in FIG. 3 based on the divided shape of the network management layer subnets (nmlSNW ₀₎ in FIG. 2 ) setting the link end point (LTP _1.2) Note subnet connection (main nmlSNC ₁₎ to generate and link end point (LTP _2.1) and the link end point (LTP _2.3) Note subnets connected between (main nmlSNC ₂₎ in between, and Create a link connection LC _5.1 inside the phase link TL ₅ . As such, when the primary subnetwork connection is generated, all paths except for the transmit / receive endpoint are selected to create a backup subnetwork connection (Backup nmlSNC) in the same manner as the main subnetwork connection.

Fourth, the network management layer subnetwork manager 16 sends a request for establishing a subnetwork connection to the lower network management layer subnetwork managers 24 and 32.

Fifth, the network management layer sub network manager (NSM ₁ ; 24) receiving the request for establishing a sub network connection is based on the split shape of the network management layer sub network nmlSNW ₁ of FIG. 2, as shown in FIG. _1.1.1 ) Create a main subnetwork connection (Main emlSNC _1.1 ) between the link endpoint (LTP _1.1.2 ) and the main subnetwork between the link endpoint (LTP _1.2.1 ) and the link endpoint (LTP _1.2.3 ). Set up the connection (Main emlSNC _1.2 ) and create a link connection (LC _1.1 ) inside the phase link (TL ₁ ). As such, when the primary subnetwork connection is created, all paths except for the transmit / receive endpoint are selected to create a backup emlSNC identically to the primary subnetwork connection.

Similar to the network management layer subnetwork manager 24, the network management layer subnetwork manager (NSM ₂ ; 32), which has received the request for establishing the subnetwork connection, is based on the partition shape of the network management layer subnetwork nmlSNW ₂ of FIG. 2. As shown in FIG. 3, a main subnetwork connection (Main emlSNC _2.1 ) is created between the link endpoint LTP _2.1.1 and the link endpoint LTP _2.1.2 , and the link endpoint LTP _2.3.1 and the link endpoint LTP _2.3.1 . _2.3.2 Set Main emlSNC _2.3 between them and create a link connection (LC _3.1 ) inside the phase link (TL ₃ ). In this way, when the primary subnetwork connection is created, all paths except the transmit / receive end point are selected to create a backup emlSNC identically to the main subnetwork connection.

Sixth, the network manager subnetwork managers 24 and 32 respectively send a request for establishing a subnetwork connection to their sub-element network management system. That is, the network manager layer network manager 24 sends the element manager layer network managers 38, 39, and 40, and the network manager layer network manager 34, the element manager layer network managers 45, 46, 47. Sends a request to establish a subnetwork connection.

Seventh, each element management layer sub-network manager (38, 39, 40, 45, 46, 47) received a request for establishing a sub-network connection is the main and spare parts in each element management layer sub-network (emlSNW) of FIG. Create a network connection as shown in FIG. At this time, the element management layer sub-network including the transmission / reception point specified by the user in the first process described above is defined as an access sub-network, and the connection establishment request is sent to the switch only for the connection of the main element network management layer sub-network. Therefore, in FIG. 2, the element management layer subnetwork (emlSNW _1.1 ) and the element management layer subnetwork (emlSNW _2.3 ) may include an access subnetwork including a user-specified transmit / receive link endpoint (LTP _1.1.1 / LTP _2.3.2 ). This creates the primary and spare subnetwork connections, but sends a connection establishment request to the corresponding asynchronous transfer mode switches 54-64 only for the primary subnetwork connection.

Finally, the eighth, each element management layer subnet manager (38, 39, 40, 45, 46, 47) is asynchronous transmission mode switch (54) to switch to the element management layer network connection that it creates Send a request to In this process, as shown in FIG. 3, the element management layer sub-network (emlSNW _1.1 ) and the element management layer sub-network (emlSNW _2.3. ) Have primary and preliminary element management layer sub-network connections. In this case, the element manager layer network manager 38 and the element manager layer network manager 47 request the corresponding asynchronous transmission mode switches 58 and 64 to switch only for the main element manager layer network connection.

According to the above process, as shown in FIG. 6, primary and preliminary connections are established between the transmit / receive endpoints (LTP _1.1.1 / LTP _2.3.2 ) to transmit / receive data through the virtual path through the primary connection. It becomes possible state.

In the state in which the shape of the main and spare links, such as the shown in Fig. 6 has been set, the port (Port _1.1.2) and asynchronous transfer mode switch (ATM SW _1.1) of the asynchronous transfer mode switch (ATM SW _1.1) in Fig. 1 Assuming that a failure has occurred in the link (link ₁ ) connected between the ports (port _1.2.1 ), a failed main connection is quickly switched to a spare connection by the process shown in FIG. 7. The port (port ₁ ) connecting the switches corresponds to the phase link (TL ₁ ) in FIG. Therefore, the asynchronous transfer mode switch ATM SW _1.1 notifies the phase link TL ₁ that a failure has occurred. When the phase link TL ₁ is notified of the failure, the fault is repaired through the following process as shown in FIG. 7.

First, the phase link TL ₁ 110 notifies the link connection LC _1.1 111 that a failure has occurred.

Secondly, the link connection (LC _1.1 ; 111) notifies the network management layer subnetwork connection (nmlSNC ₁ ) 112 of the notification of the failure.

Third, the network management layer subnetwork connection nmlSNC ₁ 112 notifies the primary virtual path trail 113 that a failure has occurred.

Fourth, the main virtual path trail 113 includes an access element management layer subnetwork connection (LTP) including a transmission / reception link end point (LTP) of a virtual path connection requested by a user, among the components constituting the trail. A delete request for emlSNC _1.1 (114) and emlSNC _2.3 (115) is sent to each subnet connection.

Fifth, the access subnetwork connection 114 requests the asynchronous transfer mode switch 116 to release its connection, and the access subnetwork connection 115 requests the asynchronous transfer mode switch 117 to itself. Requests to disconnect the connection, causing the access exchange containing the sending / receiving endpoint to be deleted.

Sixth, the element management layer sub-network connection (emlSNC _1.1 ; 114) and the element management layer sub-network connection (emlSNC _2.3 ; 115) indicate that the corresponding connection has been deleted at each exchange. Notify

Seventh, the main virtual path trail 113 finds out what its preliminary trail is, and sends a transfer request to the corresponding preliminary virtual path trail 118. In this case, the changeover means that the main trail has failed and the information can no longer be transmitted / received through the main trail, so the information is converted to a state in which the information can be transmitted / received through the preliminary trail.

Eighth, when the preliminary virtual path trail 118 receives a transfer request, an access element management layer subnetwork connection (Backup emlSNC _1.1 ) including the user-received transmit / receive endpoints (LTP _1.1.1 and LTP _2.3.2 ) is requested. , Backup emlSNC _2.3 ).

Ninth, each element management layer subnetwork connection (emlSNC _1.1 (119) and emlSNC _2.3 (120)) that has received a transfer request creates a switch level connection corresponding to each of the asynchronous transfer mode switches 116 and 117. Request to enable data transmission / reception over the preliminary virtual path connection.

After passing through the ninth process illustrated in FIG. 7, the data transmission / reception flow of the primary connection is switched to be possible through the preliminary connection, and most of the processing is performed on the failure notification and the control of the asynchronous transmission mode switch. The processing time is fast because it is limited to. As described above, the situation in which the main connection is switched to the preliminary connection at the switch level has a switching shape as shown in FIG. 8. That is, the switching connection between the asynchronous transfer mode switch 54; 116 and the asynchronous transfer mode switch 64; 117 uses the upper primary virtual path connection Link ₁ , Link ₄ , and Link ₃ in the normal state, but the main connection In the event of a failure, link ₂ , link ₅ , and link ₄ , which are the preliminary virtual path connections, are used.

According to the present invention as described above, since a reliable Virtual Path Connection (VPC) service is provided in an Asynchronous Transfer Mode (ATM) communication network, a preset and used data transmission / reception is used. When a failure occurs in the virtual path connection, the connection can be restored within the shortest time, and the best virtual path connection without a recovery failure probability can be applied to the network management system of the asynchronous transmission mode communication network.

In addition, a plurality of virtual channel connections (VCCs) are created in a virtual path connection (VPC) because of the nature of the asynchronous transmission mode (ATM), so that a reliable virtual path connection is provided to a communication service user from a network operator's point of view. Service delivery is important and can be an important factor in determining the success or failure of a business.

In addition, by applying a connection recovery method by a spare path defined in the present invention to provide a reliable virtual connection service from the carrier side, when a failure occurs in the preset virtual path connection, the communication service user reserves it within a short time which is almost unrecognizable. By switching to a connection, communication service downtime can be minimized and there is no possibility of failure of connection recovery due to a failure, which greatly affects the service provider's status.

On the other hand, the present invention is not limited only to the above-described embodiments, but may be modified and modified without departing from the scope of the present invention.

Claims (5)

A virtual virtual path connection in the asynchronous transmission mode according to the service grade of the virtual path connection, the primary virtual path connection for transmitting and receiving data in the normal state for the connection that requires the best reliability, and the preliminary virtual path in preparation for the failure of the primary virtual path connection Simultaneously creating a connection; And switching to the preliminary virtual path connection when a failure occurs in the main virtual path connection during data transmission / reception by the primary virtual path connection. The method of claim 1, The primary virtual path connection is established by the optimal path between the transmission / reception point requested by the user virtual path connection recovery method in an asynchronous transmission mode communication network. The method of claim 2, The preliminary virtual path connection selects a path different from the primary virtual path connection in all intermediate paths except for an access switch or access element management layer subnetwork including a transmission / reception point among the paths for the primary virtual path connection. Virtual path connection recovery method in an asynchronous transmission mode communication network, characterized in that set. The method of claim 1, The transition of the preliminary virtual path may include a step of notifying the main trail of the result of the failure to delete the access element management layer subnetwork connection constituting the main trail to block data transmission / reception through the main trail; The main trail notified of the occurrence identifies the corresponding preliminary trail and notifies the preliminary trail to request a transfer so as to transmit / receive data through the preliminary trail; Notifying a switchover to the spare element management layer subnetwork connection of the transmitting / receiving endpoint created inside the access element management layer subnetwork including the receiving / receiving endpoint, and the spare element management layer subnetwork connection notified of the switchover is asynchronous. Requests a switch to a transfer mode switch to connect the preliminary virtual path to the flow of data between transmit and receive endpoints. Virtual path connection recovery method of the asynchronous transfer mode communication network characterized in that step includes a switch to. The method of claim 4, wherein The primary and spare trails are simultaneously generated by a virtual path layer network manager that manages virtual path layer networks and layer network endpoints in asynchronous transmission mode and creates trail connections between endpoints. How to repair path associations.