KR20040001237A - Method for converting wavelenth-routing in wavelength division multiplexing transport networks - Google Patents

Abstract

PURPOSE: A method for converting a wavelength path in a WDM(Wavelength Division Multiplexing) transfer network is provided to achieve the release of an existing wavelength path and the creation of a new wavelength path through a single operation so that a wavelength path connection setup node pair can be changed without disconnecting traffic flow. CONSTITUTION: If a request message to modify a virtual topology arrives(S410), an OXC(Optical Cross-Connect) system judges whether the present OXC system and the OXC system of the next block belong to an existing wavelength path(S420). If the present OXC system and the OXC system of the next block belong to the existing wavelength path, the OXC system transfers the request message to the OXC system of the next block(S430). However, in case that the present OXC system and the OXC system of the next block don't belong to the existing wavelength path, the OXC system reserves wavelength switch setup for the conversion of path setup(S440). If the reservation of wavelength switch setup is successful, the OXC system transfers the request message to the OXC system of the next block(S430).

Description

Method for converting wavelenth-routing in wavelength division multiplexing transport networks

The present invention relates to a method of converting a wavelength path in a wavelength division multiplexed transmission network. More particularly, the present invention relates to a termination of a predetermined wavelength path and generation of a new wavelength path in a wavelength division multiplexing (WDM) transport network. The present invention relates to a method of converting a wavelength path in a wavelength division multiplexing transmission network which converts a wavelength path by an operation.

Wavelength division multiplexing is a technique for loading various types of data transmitted from different places onto a single optical fiber, and each signal is transmitted on a separate unique wavelength.

In addition, the wavelength division multiplexing transmission network using this technique utilizes an optical cross-connect system (OXC) as a node system and a wavelength division multiplexed transmission link as a transmission link.

FIG. 1 is a block diagram illustrating a wavelength division multiplexing transmission network structure 100, and has a mesh network structure consisting of an OXC system 10 and a wavelength division multiplexing transmission link 20. An external ATM (Asynchronous Transfer Mode) is asynchronous. Transmission Mode) / SDH (Synchronous Digital Hierarchy) or IP (Internet Protocol) networks are interworked using UNI (User Network Interface) signaling.

UNI signaling corresponds to a means for requesting explicit services for the establishment and termination, query and modification of the wavelength path 30 to the wavelength division multiplexed transmission network 100.

The wavelength path 30 means an end-to-end wavelength channel path in which the wavelength channels of the wavelength division multiplexed transmission link 20 are interconnected in the OXC system 10 on the wavelength division multiplexed transmission network 100.

OIF (Optical Internetworking Forum) has established the UNI standard for service interworking between WDM and external networks.

Unlike voice traffic, Internet traffic, which is growing explosively, is characterized by a dynamic flow of traffic.

With respect to such a traffic flow change, an optimal wavelength path setting state can be determined according to the traffic flow state, and when the traffic flow changes, the optimal wavelength path setting state also changes accordingly.

For example, assuming that there is a wavelength division multiplexing transport network as shown in FIG. 2A, the virtual topology in the structure of a given transport network is changed into an optimal virtual topology as shown in FIG. 2B or 2C according to a pattern change of traffic flow.

The wavelength division multiplexing transport network defines the overall wavelength routing state as a virtual topology, and improves the efficiency of the network when it can be changed from the current virtual topology to the target virtual topology that is optimal for the current traffic flow. Can be.

In addition, since the entire virtual topology means setting of several wavelength paths, the change of the virtual topology is possible by changing the setting of individual wavelength paths.

Conventionally, there has been proposed a method of modifying bandwidth or other characteristics among the characteristics of the wavelength path that is already set and operated, but there is no method that can change the pair of nodes of the wavelength path itself. In order to terminate the existing wavelength path and establish a new wavelength path.

However, this method has a problem in that the connection of the wavelength path is lost until the existing wavelength path is terminated and a new wavelength path is established, which may cause serious network degradation when the connection break time is too long.

In order to solve the above problems, an object of the present invention is to enable the termination of the existing wavelength path and the generation of a new wavelength path by one operation so that the traffic flow can be changed as much as possible without changing the connection setting node pair of the wavelength path. It is in a ship.

1 is a block diagram of a wavelength division multiplexing transmission network.

2A is a diagram illustrating an example of a wavelength division multiplexed transmission network.

2B and 2C are views showing a change of virtual topology in FIG. 2A.

3 is a diagram illustrating an example of a signaling message flow designed for conversion of a wavelength path in a wavelength division multiplexed transport network according to the present invention.

4 is a flow chart of OXC system operation when receiving the signaling message of FIG.

To this end, in the wavelength division multiplexing transmission network according to the present invention, a method of converting a wavelength path using a UNI signaling message in a wavelength division multiplexing transmission network structure composed of an OXC system and a link connecting the UNI signaling message is used. Confirming the message; A second step of reserving a switching configuration of the OXC system located in the new wavelength path if the UNI signaling message is a request message; If the UNI signaling message is a response message, executing a reserved switching setup; If the UNI signaling message is an acknowledgment message, it comprises a fourth step of confirming the execution of the switching configuration to complete the conversion of the wavelength path.

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

3 illustrates an example of a signaling message flow designed for conversion of a wavelength path in a wavelength division multiplexed transmission network according to the present invention.

The request message 310 is generated at the source node of the preset wavelength path and has parameters of ID of the wavelength path, ID of the new destination node, and an explicit wavelength path to the new destination node.

This request message 310 causes the destination node of the wavelength path to change to the newly specified destination node.

The response message 320 is a message transmitted from the destination node to the source node, and informs the source node that the setting state of the wavelength path has been successfully changed.

By receiving the response message 320, the source node recognizes that the resetting of the wavelength path was successful and sends a confirmation message 330 to the destination node.

After receiving the confirmation message 330, the destination node may perform message transmission on a new wavelength path.

4 is a flowchart of the OXC system operation when each of these signaling messages is received.

First, when an OXC system receives a request message for modification of a virtual topology (S410), whether or not the OXC system of the next stage also belongs to an existing wavelength path in the information of an explicit wavelength path to a new destination node. After the determination (S420), in this case, the request message is transmitted to the next stage OXC system (S430).

However, if the OXC system of the next stage and itself do not belong to the wavelength path to the new destination node, the wavelength switch setting for the conversion of the path setting is reserved (S440).

If the switch setting reservation is successful (S450), the request message is transmitted to the next stage OXC system (S430).

Otherwise, if the switch setting reservation according to the new wavelength path information is not successful, the response message is set to reject to the source node (S460).

When the response message arrives (S470), the OXC system determines whether the contents of the message are rejected (S480).

If the content of the response message is rejected, the reserved switch setting is released (S490) and the rejection response message is forwarded to the source node (S460). Otherwise, the reserved switch setting is executed (500) and the response message is accepted. In step S510, an acceptance response message indicating that the switch setting is executed is transmitted to the source node.

In addition, when the confirmation message arrives (S520), the OXC system forwards the confirmation message to the next stage of the OXC system (S530) to complete the setting of the new wavelength path.

Through this process, the switch setting of the wavelength path is reserved with the request message, the switch setting reserved by the response message is executed, the setting is completed with the confirmation message, and the new wavelength path is set to change the pattern of traffic flow in the optical transport network. This can make the virtual topology optimal.

As described above, the present invention can operate the transformation of the virtual topology in a single operation in the wavelength routing wavelength division multiplexed transport network structure operating in the form of UNI signaling, thereby providing a configuration transformation to the optimal topology without interruption of traffic. As a result, it is possible to achieve higher operational efficiency.

Claims (5)

In a method of converting a wavelength path using a User Network Interface (UN) signaling message in a wavelength division multiplexed transport network structure consisting of an optical cross-connect system (OXC) system and a link connecting the same, A first step of confirming the UNI signaling message; If the UNI signaling message is a request message, a second step of reserving a switching configuration of the OXC system located in a new wavelength path; Performing the reserved switching setting if the UNI signaling message is a response message as a result of the checking; And if the UNI signaling message is an acknowledgment message, confirming the execution of the switching setting and completing the conversion of the wavelength path, and converting the wavelength path in the wavelength division multiplexing transmission network. The method of claim 1, The request message, A method of converting a wavelength path in a wavelength division multiplexing transmission network, wherein the method is generated at a source node of the wavelength path and includes an identification of the wavelength path, an ID of a new destination node, and a wavelength path to the new destination node. . The method according to claim 1 or 2. The switching setting reservation, A fifth step of forwarding the request message to the next stage OXC system if the OXC system and the next stage OXC system are included in the wavelength path to the new destination node of the request message; A sixth step of, if the OXC system and the next stage of the OXC system are not included in the wavelength path to the new destination node of the request message, reserving the switching configuration of the OXC system for the destination node wavelength path; And And if the reservation fails, transmitting a response message indicating the rejection to the source node. The method of claim 1. The switching setting execution, An eighth step of canceling the reserved switching reservation and forwarding the response message to a source node if the content of the response message is rejected; And if the content of the response message is not rejected, executing the reserved switching reservation and delivering a response message of the acceptance content to a source node. . The method of claim 1. Confirmation of the switching setting, And a tenth step of delivering the confirmation message to an OXC system of a next stage.