JP2003143206A - Optical communication network, program, and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transfer burst data efficiently and to effectively utilize a wavelength resource. SOLUTION: In order that a node can efficiently acquire a request of cut- through path setting or release or a path switching request, an arrangement of insertion of a preamble and control information in succession to the preamble to the data is made in advance. The node monitors the preamble and extracts the control information in succession to the preamble to acquire the request of cut-through path setting or release or the path switching request.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention is used in optical communication.
The present invention relates to an optical burst data transfer technique in a communication network that uses an optical wavelength as a communication medium for burst data transfer.

[0002]

2. Description of the Related Art An ordinary IP (Internet Pr
In data transfer, a plurality of routers are arranged from the start point to the end point, and the data is transferred via this router. At this time, each router determines the router to be transferred next by referring to the IP address given to the packet and transfers the packet.

In such an optical communication network, when reading the header information of a packet, an optical signal is first converted into an electric signal and then read. The router determines the router to be transferred next according to the IP address thus read.

Further, when transferring data in bursts, since the transfer efficiency is not good because the IP address is read for each packet, a cut-through path is previously set between the starting point and the end point. Since it is set and the IP header does not need to be read in this cut-through path section, the optical signal can be transferred at high speed as it is.

[0005]

In such conventional optical communication, it is necessary to set a cut-through path in advance when transferring burst data using the cut-through path. In order to set the cut-through path in advance, each router passing from the starting point to the end point requests that the cut-through path be set, and each router responds to this request, and the pre-setting of the cut-through path is completed for the first time. To do.

At this time, looking at the cut-through path setting procedure in each router, first, the header information of the arriving optical IP packet is converted into an electric signal, and the information corresponding to the cut-through path setting request is included therein. Is read, and if the setting request is included, the wavelength for the cut-through path setting is selected, and if the wavelength can be selected, the cut-through path setting is actually performed. And for the wavelength for which the cut-through path is set,
Since it is no longer necessary to read the header information of the IP packet, the settings are changed so that the IP packet is transferred as an optical signal in a distinctive manner from other wavelengths.

However, such a setting procedure requires a considerable amount of time. For example, it is assumed that it takes 2t seconds to set the cut-through path. If it takes 3 t seconds to transfer the burst data using this cut-through path, it takes 5 t seconds to set the cut-through path and complete the transfer of the burst data. In this example, approximately half of the 5t seconds required for burst data transfer was used for setting the cut-through path. If the time required for such advance cut-through path can be allotted for data transfer, further improvement in transfer efficiency can be expected.

The present invention has been made against such a background, and an optical communication network, a program and a recording capable of efficiently performing burst data transfer and effectively utilizing wavelength resources are provided. The purpose is to provide a medium.

[0009]

According to the present invention, a preamble and control information following this preamble are inserted into data in advance so that a node can efficiently obtain a request for setting or releasing a cut-through path or a route switching. The node is characterized in that the node can acquire a request for setting or releasing a cut-through path or switching a route by monitoring the preamble and extracting control information following the preamble.

Thus, if it is known in advance that the control information will follow the preamble, the CPU processing determines whether or not a request for setting or releasing a cut-through path or a route switching request is included in the incoming data. It is possible to shorten the processing procedure for identifying. Also, after setting the cut-through path, by monitoring only that cut-through path, it is possible to obtain a request for route switching or release of that cut-through path, so there is no need to monitor over multiple wavelengths, and the monitoring procedure can be changed. It can be simplified. Therefore, the procedure and time required for setting or releasing the cut-through path or switching the route can be shortened as compared with the related art. Moreover, since the control wavelength of the cut-through path and the setting wavelength of the cut-through path are the same wavelength, the wavelength resource can be effectively used.

That is, a first aspect of the present invention is to provide a transmission-side edge node accommodating a data transfer source, a reception-side edge node accommodating a data transfer destination, the transmission-side edge node and the reception-side edge node. And a means for setting and releasing a cut-through path passing through the relay node between the transmission-side edge node and the reception-side edge node, and the transmission-side edge node, It is an optical communication network in which a plurality of different wavelengths for data transfer are set between the relay node and the receiving edge node.

A feature of the present invention is that a preamble and control information for requesting setting or release of a cut-through path or path switching following the preamble are inserted in the data transfer wavelength, and the cut-through path is provided. Means for setting and releasing the preamble and control information following the preamble for each of the plurality of wavelengths for data transfer, and control information following the preamble according to the monitoring result of the first monitoring means. Request the setting of the cut-through path, the means for setting the cut-through path according to the request, and the preamble and the preamble for the burst data transferred through the cut-through path after the cut-through path is set by this setting means. Control information that continues And a means for executing the cut-through path route switching according to the request when the control information following the preamble requests the cut-through path route switching in accordance with the monitoring result of the second monitoring means. And a means for releasing the setting of the cut-through path when the control information following the preamble requests the release of the setting of the cut-through path according to the monitoring result of the second monitoring means.

As described above, the delimiter of the burst data can be identified by the preamble, and further the control information can be inserted after the preamble to instruct the handling of the burst data, so that the route can be routed to one cut-through path. It is possible to serially transfer a plurality of burst data having different numbers. As a result, burst data transfer can be performed efficiently and wavelength resources can be effectively used.

A second aspect of the present invention is a program, which is installed in an information processing device so that the information processing device passes through a transmitting side edge node, a relay node and a receiving side edge node in an optical communication network. As a function of setting and releasing a cut-through path, the preamble and control information for requesting the setting or release of the cut-through path or the path switching subsequent to the preamble are inserted in the data transfer wavelength, and the plurality of data transfer wavelengths The first monitoring function that monitors the preamble and the control information that follows this preamble for each, and when the control information that follows the preamble requires the setting of a cut-through path according to the monitoring result of this first monitoring function, the cut-through path is set according to that request. And the function to set After the cut-through path is set by the function that performs the pre-amble and the pre-amble according to the monitoring result of the second monitoring function, the pre-amble and the control information following the pre-amble are monitored for the burst data transferred through the cut-through path. When the subsequent control information requests the cut-through path route switching, the function of executing the cut-through path route switching according to the request, and the control information following the preamble according to the monitoring result of the second monitoring function is the cut-through path switching function. When a setting release request is issued, the program realizes a function of releasing the cut-through path setting according to the request.

A third aspect of the present invention is a recording medium readable by the information processing device, in which the program of the present invention is recorded. By recording the program of the present invention on the recording medium of the present invention, the information processing apparatus can install the program of the present invention using this recording medium. Alternatively, the program of the present invention can be installed in the information processing apparatus directly from a server holding the program of the present invention via a network.

As a result, it is possible to realize an optical communication network capable of efficiently performing burst data transfer by an information processing device such as a computer device and effectively using wavelength resources.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical communication network according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a conceptual diagram of an optical communication network according to an embodiment of the present invention. FIG. 2 is a diagram showing a preamble and a control packet inserted in data. FIG. 3 is a diagram showing a preamble and control information inserted in burst data. 4 to 6 are diagrams showing the configuration of the monitoring function of the embodiment of the present invention.

In the embodiment of the present invention, the transmission-side edge node S and the reception-side edge node R are described separately for the sake of clarity, but in reality, the edge node functions as the transmission side. Both functions of the receiver and the receiver are provided, and bidirectional communication can be performed.

The present invention, as shown in FIG. 1, includes a transmitting side edge node S accommodating a data transfer source, a receiving side edge node R accommodating a data transfer destination, a transmitting side edge node S and a receiving side edge node. The relay nodes L1 to L4 arranged between the relay node L and the relay node R, and the function of setting and releasing cut-through paths passing through the relay nodes L1 to L4 between the transmission-side edge node S and the reception-side edge node R. ,
This is an optical communication network in which a plurality of different wavelengths for data transfer are set among the transmission side edge node S, the relay nodes L1 to L4, and the reception side edge node R, respectively. The function of setting or releasing the cut-through path is performed by the transmitting side edge node S, the relay nodes L1 to L4, and the receiving side edge node R.
Alternatively, one or a plurality of distributed devices may be arranged in the optical communication network outside the node as a device for collectively managing the setting and release of the cut-through path. The function is a well-known technique, and illustration and description thereof will be omitted.

Here, as a characteristic of the present invention, as shown in FIG. 2, control information for setting or releasing a preamble and a cut-through path following this preamble or for switching a route is provided in the data transfer wavelength. A control packet including a control packet including a preamble and control information following the preamble for each of the plurality of data transfer wavelengths is inserted, and the function of setting or releasing the cut-through path is When the control information following the preamble requests the setting of the cut-through path according to the monitoring result of No. 2, the cut-through path is set according to the request, and as shown in FIG. 3, the monitoring unit 2 sets the cut-through path after the cut-through path is set. Is the preamble for the burst data transferred through the cut-through path Also, the function of monitoring the control information following the preamble and setting or releasing the cut-through path follows the request when the control information following the preamble requests route switching of the cut-through path according to the monitoring result of the monitoring unit 2. When the control information following the preamble requests the release of the cut-through path setting according to the monitoring result of the monitoring unit 2, the cut-through path setting is released according to the request. .

Next, the operation of the optical communication network according to the embodiment of the present invention will be described. As shown in FIG. 4, data as shown in FIG. 2 is transferred to the optical transmission line 7. The optical switch 1 normally connects the optical transmission line 7 to the optical cross connect 3.

The optical switch 1 connects the optical transmission line 7 to the monitoring unit 2 when detecting the preamble inserted in the data to be transferred. As a result, the control information following the preamble is introduced into the monitoring unit 2. When detecting passage of control information, the optical switch 1 connects the optical transmission line 7 to the optical cross connect 3 again.

The monitoring unit 2 analyzes the received control information, and when it recognizes that the control information is a cut-through path setting request, outputs the monitoring result to the function for setting or releasing the cut-through path. . The function of setting or releasing the cut-through path that has received the monitoring result sets a predetermined cut-through path. The cut-through path is set according to the above procedure.

After the cut-through path is set, FIG.
As shown in, burst data is transferred using this cut-through path. The optical switch 1 connects the optical transmission line 7 to the monitoring unit 2 when detecting the preamble inserted in the burst data to be transferred. As a result, the control information following the preamble is introduced into the monitoring unit 2. Optical switch 1
When detecting the passage of control information, reconnects the optical transmission line 7 to the optical cross connect 3.

The monitoring unit 2 analyzes the received control information, and when it recognizes that the control information is a cut-through path route switching request (# 3, # 1) as a result, the monitoring result is sent to the optical cross-connect. Output to 3. The optical cross connect 3 that has received this monitoring result performs path switching of a predetermined cut-through path. In the example of FIG. 3, the route # 3 →
Switching is performed with the route # 1. The route switching of the cut-through path is performed according to the above procedure.

Further, the monitoring unit 2 analyzes the received control information and, as a result, when recognizing that the control information is a cut-through path release request (R), sets or releases the cut-through path based on the monitoring result. Output to the function. The function of setting or releasing the cut-through path, which has received the monitoring result, releases the predetermined cut-through path. The cut-through path is released according to the above procedure.

Next, a configuration different from that of FIG. 4 for the control unit 2 to monitor the control information will be described with reference to FIG. The optical signal output from the optical transmission line 7 is branched by the optical coupler 4, and a part of the optical signal is input to the monitoring unit 2. The monitoring unit 2 can recognize the arrival of the control information by detecting the preamble and can receive the control information following the preamble.

Next, with reference to FIG. 6, description will be given of a configuration different from those of FIGS. 4 and 5 for the monitoring unit 2 to monitor the control information. In the configuration of FIG. 6, one monitoring unit 2 can monitor a plurality of optical transmission lines 7-1 to 7-n.

The optical communication network of the present invention is installed in a computer device as an information processing device so that the computer device has the transmitting side edge node S, the relay nodes L1 to L4 and the receiving side edge node R in the optical communication network. As a function of setting and releasing a cut-through path via the preamble and control information requesting setting or release of the cut-through path or route switching following the preamble is inserted in the data transfer wavelength, and a plurality of the data transfer is performed. The first monitoring function that monitors the preamble and the control information that follows this preamble for each wavelength for use, and when the control information that follows the preamble requires the setting of a cut-through path according to the monitoring result of this first monitoring function, follow that request. Cut through path Setting function, a second monitoring function that monitors a preamble and control information following the preamble for burst data transferred through the cut-through path after the cut-through path is set by the setting function, and the second monitoring function. When the control information following the preamble requests switching of the cut-through path according to the monitoring result of the function of executing the switching of the path of the cut-through path according to the request, and the preamble according to the monitoring result of the second monitoring function. When the subsequent control information requests the release of the cut-through path setting, a program that realizes the function of releasing the cut-through path setting according to the request is installed in the computer apparatus, thereby realizing using the computer apparatus. be able to. The first and second monitoring functions are functions corresponding to the monitoring unit 2 shown in FIGS. 4 to 6.

By recording the program of the present invention in the recording medium of the present invention, the computer device can install the program of the present invention using this recording medium. Alternatively, the program of the present invention can be installed in the computer device directly from a server holding the program of the present invention via a network.

As a result, it is possible to realize an optical communication network capable of efficiently performing burst data transfer and effectively utilizing wavelength resources without the need for setting a cut-through path in advance by a computer device. it can.

[0032]

As described above, according to the present invention,
Burst data transfer can be performed efficiently and wavelength resources can be effectively used.

[Brief description of drawings]

FIG. 1 is a conceptual diagram of an optical communication network according to an embodiment of the present invention.

FIG. 2 is a diagram showing a preamble and a control packet inserted in data.

FIG. 3 is a diagram showing a preamble and control information inserted in burst data.

FIG. 4 is a diagram showing a configuration of a monitoring function according to the embodiment of the present invention.

FIG. 5 is a diagram showing a configuration of a monitoring function of the embodiment of the present invention.

FIG. 6 is a diagram showing a configuration of a monitoring function according to the embodiment of the present invention.

[Explanation of symbols]

1 Optical switch 2 monitoring section 3 optical cross connect 4, 4-1 to 4-n Optical coupler 7, 7-1 to 7-n Optical transmission line

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Eiji Oki             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F-term (reference) 5K030 GA01 GA08 HA08 HD03 JA14                       JL03 KX20 LA17 LB09

Claims (3)

[Claims] 1. A transmission-side edge node accommodating a data transfer source, a reception-side edge node accommodating a data transfer destination, and a relay node arranged between the transmission-side edge node and the reception-side edge node. Further comprising means for setting and releasing a cut-through path passing through the relay node between the transmission-side edge node and the reception-side edge node, the transmission-side edge node, the relay node, and the reception-side edge node In the optical communication network in which a plurality of different wavelengths for data transfer are respectively set between, and the control information for requesting the setting or release of the preamble and the cut-through path following this preamble or the path switching in the wavelength for data transfer And a means for setting and releasing the cut-through path includes a plurality of wavelengths for data transfer. First monitoring means for monitoring the preamble and the control information following this preamble for each, and when the control information following the preamble requires the setting of a cut-through path according to the monitoring result of this first monitoring means, the cut-through path is set according to the request. And a second monitoring means for monitoring the preamble and control information following the preamble for the burst data transferred through the cut-through path after the cut-through path is set by the setting means. When the control information following the preamble requests switching of the cut-through path according to the monitoring result of the means, means for executing the switching of the path of the cut-through path according to the request, and the preamble according to the monitoring result of the second monitoring means. Control information following There optical network, characterized in that a means for releasing the setting of the cut-through path along the request when requesting the release of the setting of the cut-through path. 2. A function for setting and releasing a cut-through path passing through a transmission-side edge node, a relay node, and a reception-side edge node in an optical communication network by installing the information processing device in the information processing device, Control information for setting or releasing a preamble and a cut-through path following this preamble or requesting route switching is inserted in the wavelength for data transfer, and the preamble and the control information following this preamble for each of the plurality of wavelengths for data transfer are inserted. The first monitoring function to monitor, the function to set the cut-through path according to the request when the control information following the preamble requires the setting of the cut-through path according to the monitoring result of this first monitoring function, and this setting function Cut-through path After that, the second monitoring function that monitors the preamble and control information following this preamble for the burst data transferred through the cut-through path, and the control information that follows the preamble according to the monitoring result of this second monitoring function When requesting route switching, a function to perform route switching of the cut-through path according to the request, and when the control information following the preamble according to the monitoring result of the second monitoring function requests release of the setting of the cut-through path. A program that realizes the function of releasing the setting of the cut-through path according to the request. 3. A recording medium readable by the information processing device, in which the program according to claim 2 is recorded.