KR20010056912A - Method for controlling dynamic wavelength path in wdm mesh networks - Google Patents

Abstract

PURPOSE: A method of controlling dynamic wave path in a WDM(Wavelength Division Multiplexing) network structure is provided to realize a quick setting and releasing of wave path. CONSTITUTION: Whenever setting and releasing the wave path, the set data of the wave switch and the data of wave band usage status of each optical fiber are collected and stored in the internal data structure. It is determined if there is wave path generating/releasing request. If there is the release request, the wave band occupied by the one to be request is converted into unoccupied state. After the status data are corrected, the second step is repeated. If there is the setting request, the available path between the two nodes requiring the wave path, the path and wave group requesting the minimal switch setting variation among wave groups are selected. According to the path and wave group, the wave switch in each optical divider coupler device is controlled to select the wave path according to the request. In order to match the current wave switch(123/1-123/4) setting status and the wave band usage status in the network with the contents of the internal data structure, the contents of the internal data structure are corrected.

Description

Dynamic Wavelength Path Control Method in Wavelength Division Multiplexing Network Structure TECHNICAL CONTROLLING DYNAMIC WAVELENGTH PATH IN WDM MESH NETWORKS

The present invention relates to a method for controlling a wavelength path in a mesh network topology using a wavelength division multiplexing (WDM) transmission scheme, and more particularly, to set up a dynamic wavelength path using a central control system. And a dynamic wavelength path control method in a wavelength division multiplexed network structure suitable for controlling release.

In general, each node of the network is implemented as an optical cross connect device (OXC), each of which is provided with wavelength switch elements for branch coupling of the wavelength path. At this time, the switching setting of the wavelength switch elements in each optical branch coupling device is controlled by one central control system through an independent control channel, i.e., the central control system is appropriate whenever a request for setting and releasing a wavelength path is generated. The switching configuration accommodates a given request.

On the other hand, the conventional network operation method as described above presupposes various matters regarding the routing and the wavelength assignment of the wavelength path at the time of initial network setup, assuming the constant wavelength path demand, and does not modify it when the network is operated. If not or modified, control wavelength routing and release in the form of relatively long operating times.

However, the above-described conventional method is suitable for a transmission network structure mainly accommodating voice telephone traffic, but is not suitable for a transmission network structure mainly made up of the Internet data traffic, which has recently been increasing rapidly.

That is, Internet data traffic is connectionless compared with voice telephone traffic, and the data bit rate generated per unit time is not constant, and it is transmitted by statistical multiplexing method. It should be possible to set up and release at the network level, and the conventional network operation method is inadequate to accommodate the Internet data traffic. For details on the characteristics of Internet data traffic and the requirements of the transport network structure to mainly accommodate Internet data traffic, see John L. Strand, "The Internet, IP, And The Optical Layer", Volume 1, Page 4-6. Proceedings of APCC / OECC′99.

Accordingly, the present invention is to solve the above problems of the prior art, dynamic wavelength path control in the wavelength division multiplexing network structure that can realize the fast setting and release of the wavelength path required in the wavelength division multiplexing (WDM) network structure The purpose is to provide a method.

In order to achieve the above object, the present invention provides a wavelength division multiplexing network structure having a central control system and a plurality of optical branch coupling devices whose wavelength paths are controlled by switching control signals provided from the central control system through respective control channels. In the method for controlling the wavelength path, each time the wavelength path is set and released according to the wavelength path setting request and / or the release request, information about the wavelength band setting and the usage status of the wavelength band of each optical fiber are collected and internally collected. A first process of storing or updating the data structure; A second step of checking whether there is a wavelength path generation request or a release request; As a result of the check, if there is a request for the release of the wavelength path, the second process is performed after converting the wavelength band used by the release-required wavelength path into an unused state, modifying the current state information of the wavelength band stored in the internal data structure. Performing a third process repeatedly; A fourth step of selecting a path and wavelength combination that requires the smallest switch setting change among the possible paths and wavelength combinations between the two nodes requiring the wavelength path if the wavelength path setting request is found as the result of the check; A fifth process of setting a wavelength path according to the wavelength path setting request by controlling a wavelength switch in each optical branch coupling device according to the selected path and wavelength combination; And a sixth step of modifying the contents of the internal data structure so that the current state of the wavelength switch setting and the current usage of the wavelength band match the contents of the internal data structure. do.

1 is a block diagram showing an example of a wavelength division multiplexing (WDM) network structure;

2 is a block diagram showing an example of the optical branch coupling device shown in FIG.

3 is a flowchart illustrating a process of dynamically controlling a wavelength path in a wavelength division multiplexed network structure according to a preferred embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

110: central control system 112: wavelength switch control channel

120: optical branch coupling device 121/1-121/4: wavelength division demultiplexer

123/1-123/4: Wavelength switch 125/1-125/4: Wavelength division multiplexer

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

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

First, a key technical aspect of the present invention is to collect and store (or update and store) current wavelength switching setting information and wavelength band usage status information in association with the setting and release states of a wavelength path, and to store the wavelength path generation request. By selecting paths and wavelength combinations in which the number of optical branch coupling devices is minimized based on the information, it is possible to realize stable network operation by quickly setting and releasing required wavelength paths.

FIG. 1 is a block diagram illustrating an example of a wavelength division multiplexing (WDM) network structure, and shows a grid network composed of one central control system 110 and six optical branch coupling devices 120.

Referring to FIG. 1, the central control system 110 controls the wavelength switch control channel 112 according to the current wavelength switching setting information and wavelength band usage status information which is collected and stored whenever a wavelength path setting request or release request is generated. By transmitting a switching control signal to the wavelength switch in each optical branch coupling device 120 through, to control the setting and release of the required wavelength path.

FIG. 2 is a block diagram of an optical splitter coupling apparatus shown in FIG. 1 as an example, and includes four wavelength division demultiplexers 121/1-121/4 and four wavelength switches 123/1. 123/4) and four wavelength division multiplexers 125/1-125/4.

FIG. 2 illustrates an example in which four wavelength bands are multiplexed and transmitted to one fiber. The wavelength division multiplexed signals carried on the optical fibers of the input sides I1 to I4, that is, the wavelengths λ1, λ2, λ3, and λ4 are respectively Each wavelength is divided by the wavelength division demultiplexer 121 /-121/4 and then switched to each other through corresponding wavelength switches 123/1-123/4. Here, each wavelength switch 123/1-123/4 switches each wavelength in response to a switching control signal provided from the central control system 110 of FIG. 1 to the control channel 112.

Next, each of the wavelengths λ 1, λ 2, λ 3, and λ 4 switched through each wavelength switch 123/1-123/4 again wavelength-multiplexes each wavelength division multiplexer 125/1-125/4. And then transferred to the optical fiber on the output side (O1-O4).

Next, a process of performing dynamic wavelength path control according to the present invention in the wavelength division multiplexing network structure having the above-described configuration will be described.

3 is a flowchart illustrating a process of dynamically controlling a wavelength path in a wavelength division multiplexed network structure according to a preferred embodiment of the present invention.

Referring to FIG. 3, in the central control system of FIG. 1, the setting information of the wavelength switch in the wavelength division multiplexing network and the wavelength band usage status of each optical fiber each time the wavelength path is controlled according to the wavelength path setting request and / or the release request. Information about the data is collected and stored or updated in an internal data structure (step 302). That is, when the wavelength path is set or released, the wavelength switch setting or the wavelength band usage status is changed. The central control system 110 always maintains the current situation in the network and the stored information of the internal data structure.

Next, in step 304, it is checked whether there is a wavelength path generation request or a wavelength path release request. If the check here determines that there is a wavelength path release request, the central control system 110 switches the wavelength switch. The information on the set state is kept as it is, only the information on the wavelength band usage status is corrected, and then the state is converted to the state in which the wavelength path required to be released is not used (step 306), and the processing is performed in the initial setting stage. Return to 304.

If it is determined in the step 304 that there is a wavelength path setting request, the central control system 110 refers to the internal data structure to determine the shortest distance path information and each path between two nodes requiring the wavelength path. Information about the unused wavelength band of the image is extracted (step 308), and then it is checked whether the extracted path and wavelength band combination exist (step 310).

If the extracted path and wavelength band combination do not exist as a result of the check in step 310, the wavelength path cannot be set due to insufficient wavelength resources (step 312), and the process is initially set. Return to 304.

Unlike the above, if the check in step 310 indicates that one or more path and wavelength band combinations exist, for all extracted path and wavelength combinations, if the corresponding path and wavelength combination is selected for the wavelength path setting, the central control is performed. The system 110 selects a path and wavelength combination in which the number of optical branch coupling devices for which the internal wavelength switch setting should be changed in the current state is the minimum (step 314).

Then, the central control system 110 applies the control signal to the wavelength switch in accordance with the selected path and wavelength combination to set the optimal wavelength path (step 316), the current state of the wavelength switch setting and the use of the wavelength band in the network By modifying to match the content of this internal data structure (step 318), wavelength path control for the required wavelength path setting request is completed.

As described above, according to the present invention, a path and wavelength combination that requires the smallest wavelength switch setting change among the various possible path and wavelength combinations between two nodes requiring a wavelength path to accommodate the wavelength path setting request is selected. In this case, the wavelength path setting can be faster than the conventional method.

In addition, the present invention only changes the wavelength band usage status information of the internal data structure when the wavelength path release request is made. Therefore, when the demand for the same wavelength path is given later, the wavelength path setting is faster. This is possible.

Furthermore, the present invention can accommodate a given wavelength path setting and release request with only a minimum network setting change, thereby minimizing interference to a wavelength path that is already set and in operation, thereby realizing more stable operation of the network.

Claims (1)

A method for controlling a wavelength path in a wavelength division multiplexed network structure having a central control system and a plurality of optical branch coupling devices whose wavelength path is controlled by switching control signals provided from the central control system through each control channel, Whenever the wavelength path is set and released according to the wavelength path setting request and / or the release request, information about the wavelength switch setting and the usage status of the wavelength band of each optical fiber are collected and stored or updated in an internal data structure. 1 course; A second step of checking whether there is a wavelength path generation request or a release request; As a result of the check, if there is a request for the release of the wavelength path, the second process is performed after converting the wavelength band used by the release-required wavelength path into an unused state, modifying the current state of the wavelength band stored in the internal data structure. Performing a third process repeatedly; A fourth step of selecting a path and wavelength combination that requires the smallest switch setting change among the possible path and wavelength combinations between two nodes requiring the wavelength path if the check results in the wavelength path setting request; A fifth process of setting a wavelength path according to the wavelength path setting request by controlling a wavelength switch in each optical branch coupling device according to the selected path and wavelength combination; And And a sixth step of modifying the contents of the internal data structure such that the current in-network wavelength switch setting state and the wavelength band usage state correspond to the contents of the internal data structure.