JP2003324465A - Multilayer optical network and node and path setting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To efficiently operate a network by automatically setting O-LSP and E-LSP by calculating a path optimal for each node. <P>SOLUTION: In a timing of generation of traffic, the required path is set. For example, the path of the O-LSP is calculated by the node of the E-LSP and based upon the calculated result, the node of the O-LSP sets the path of the relevant O-LSP. Otherwise, the path of the O-LSP is calculated by the node of the E-LSP and the node of the O-LSP decides whether or not the path can be set based upon the calculated result. When the path can be set, the path is set but when the path can not be set, the path is calculated again and the path of the relevant O-LSP is set. Otherwise, the node of the E-LSP sends a path setting request of the O-LSP and the node of the O-LSP calculates the path of the O-LSP and decides whether setting is possible or not. When setting is possible as a result, the relevant O-LSP is set. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a path setting technique in an optical network having a multi-layer structure of an optical path by an optical wavelength and an electric path using the optical path.

[0002]

2. Description of the Related Art There is known an optical network including a plurality of sub-networks for performing packet-based switch and transfer, an optical transmission line connecting the sub-networks, and a node terminating the optical transmission line. .

In such an optical network, at both ends of an optical wavelength link composed of an optical transmission line and a node,
Optical wavelength switching capability (LSC is noted) that allows switching in optical wavelength units and packet switching capability (P that allows switching in packet units)
SC) are provided respectively. Furthermore, an optical wavelength link equipped with LSCs at both ends (referred to as O-LSP)
Is a packet link with PSC on both ends (E-LSP
It is included in).

Such an optical network is an O-LSP.
Since it has a two-layer structure of E-LSP and E-LSP, it is called a multi-layer optical network. In such a multilayer optical network, when performing packet IP transfer,
Since the optical path is transferred as an optical signal packet by the O-LSP in the intermediate path, a large number of advantages of the optical transfer path, such as an increase in the transfer rate and the number of multiplexed signals, can be achieved as compared with the case where the entire path is transferred as an electric signal packet. It is possible to obtain various effects.

[0005]

In the conventional multi-layer optical network, the O-LSP and the E-LSP are operated independently, and the O-LSP and the E-LSP are operated depending on the demand of the E-LSP and the traffic fluctuation.
-The LSP cannot be changed freely.

That is, since the O-LSP is fixed by a leased line or the like, there is a problem that it is not possible to immediately respond to a change in packet traffic, or the resources of the O-LSP cannot be effectively used. Further, when changing the O-LSP, there is a problem that it is necessary to apply to the optical network operating company and manually switch and set the O-LSP by the optical network operating company.

The present invention has been made against such a background, and each node calculates an optimum route and automatically sets an O-LSP and an E-LSP, which is efficient. An object is to provide a multi-layer optical network, a node, a program, a recording medium, and a path setting method that can be operated.

[0008]

The present invention is characterized in that the E-LSP node including the O-LSP controls the path setting of the O-LSP. This allows the E-LSP
Since it is possible to flexibly set the O-LSP route according to the traffic condition of the node, efficient multi-layer optical network operation can be realized.

That is, a first aspect of the present invention is to provide a plurality of sub-networks for switching and transferring in packet units, an optical transmission line connecting the sub-networks, and a node terminating the optical transmission line. The optical wavelength link constituted by the optical transmission line and the node is provided with an LSC capable of switching in an optical wavelength unit and a PSC capable of switching in a packet unit, respectively, at both ends, and an OSC having an LSC at both ends. LSP and this O-LS
It is a multi-layer optical network having a two-layer structure including an E-LSP including P and PSCs at both ends.

Here, the feature of the present invention is that the route of the O-LSP is automatically taken into consideration in consideration of route information including route cost, resource consumption, and traffic volume in response to the setting request of the E-LSP. There is a means to set to.

A second aspect of the present invention is a node applied to the multi-layer optical network of the present invention, wherein the O-LSP is set in response to a setting request of the E-LSP.
The node is characterized in that it is provided with means for automatically setting the route in consideration of route information including route cost, resource consumption, and traffic volume.

As described above, in the multi-layer optical network of the present invention, a necessary path can be set in consideration of the route information including the route cost, the resource consumption, and the traffic amount triggered by the generated traffic, so that an efficient network is achieved. Can operate.

The means for setting is provided in a node requesting the setting of the E-LSP to calculate the path of the O-LSP, and the means for calculating is provided in a node on the originating side of the O-LSP. O-LS based on the calculation result of
It is desirable to have means for setting the path of P.

As a result, the O-LSP path setting is performed by the E-
It can also be done by the node requesting the setting of the LSP. Therefore, the user who uses the E-LSP can also set the path of the O-LSP included therein according to the request, so that the convenience of the user can be improved and the network operator can O-LSP
E-LSP
By optimally setting the O-LSP route according to the traffic situation of (3), the labor of O-LSP route setting can be saved, and efficient multi-layer optical network operation can be performed.

Alternatively, the setting means is the E-
The O-LS provided in the node requesting the setting of the LSP
Means for calculating the path of P and transmitting a path setting request based on the calculation result; and the calculation included in the path setting request after the path setting request is provided in the node on the originating side of the O-LSP. Based on the result, it is judged whether or not the route can be set. If the route can be set, the route is set based on the calculation result.
Means for setting the route of the SP can also be provided.

According to this, under the situation where the O-LSP route is frequently updated, the time when the node requesting the E-LSP setting calculates the O-LSP route and sends the path setting request, , There is a time lag between the time when this path setting request arrives at the node on the originating side of the O-LSP and the node on the originating side actually sets the route of the O-LSP.
-It is possible to deal with a case where the traffic situation of the LSP changes.

Alternatively, the setting means is the E-
The O-LS provided in the node requesting the setting of the LSP
A means for transmitting a path setting request of P and a node which can be set for the O-LSP, calculates the path of the O-LSP based on the path setting request, and determines whether the O-LSP can be set. The result is notified to the means for transmitting the path setting request and, if it can be set, the OL
Means for setting the SP can also be provided.

According to this, the node requesting the setting of the E-LSP does not perform the route calculation of the O-LSP, and
-LSP route is not set, and O-LSP
The calculation of the route is entrusted to the node that can set the O-LSP. This reduces the load on the node requesting the E-LSP setting. However, the node requesting the setting of the E-LSP is an O-L to the node capable of setting the O-LSP.
A SP path setting request can be made. At that time, E-
The node requesting the setting of the LSP can select the node that can set the O-LSP most convenient for the own node. As a result, the path and the light wavelength can be secured with high probability.

For example, the means for transmitting the path setting request selects the node having the smallest number of hops from the own node or the total cost of the link as the node capable of setting the O-LSP, and transmits the path setting request. Means for doing so.

Alternatively, the setting means is the E-
The O-LS provided in the node requesting the setting of the LSP
A means for transmitting a path setting request of P and a node which can be set for the O-LSP, calculates the path of the O-LSP based on the path setting request, and determines whether the O-LSP can be set. Means for notifying the means for sending the path setting request, and means for sending the path setting request, when a plurality of settable notifications by the notifying means from a plurality of nodes arrive, Of the nodes that have sent the settable notification, the node that has received the settable notification earliest or the node that has the smallest number of hops or the total link cost from the own node actually requests the setting of the O-LSP. Means can also be provided.

According to this, the node requesting the setting of the E-LSP does not perform the route calculation of the O-LSP, and
-LSP route is not set, and O-LSP
The calculation of the route is entrusted to the node that can set the O-LSP. This reduces the load on the node requesting the E-LSP setting. However, the node requesting the setting of the E-LSP can make the path setting request of the O-LSP to the node capable of setting the plurality of O-LSPs, and at this time, request the setting of the E-LSP. A node consists of multiple O-
It is possible to select the node that can set the O-LSP most convenient for the own node from the settable notifications from the nodes that can set the LSP. The node in which the most convenient O-LSP can be set is, for example, the node in which the settable notification arrives earliest or the node in which the number of hops from the own node or the total cost of links is the smallest. As a result, the path and the light wavelength can be secured with high probability.

A third aspect of the present invention is a program which, when installed in an information processing device, causes the information processing device to realize a function corresponding to a node applied to the multilayer optical network of the present invention.

Here, the feature of the present invention is that the route of the O-LSP is automatically taken into consideration in consideration of route information including route cost, resource consumption, and traffic volume in response to the setting request of the E-LSP. It is about to realize the function to set to.

As the setting function, the E-LSP is used.
Of the O-LSP that is provided in the node that requests the setting of the
It is desirable to realize the function of setting the path of the LSP.

Alternatively, as a function of the setting, the O- is provided in the node requesting the setting of the E-LSP.
A function of calculating the path of the LSP and transmitting a path setting request based on the calculation result, and the calculation included in the path setting request after receiving the path setting request provided in the node on the originating side of the O-LSP Based on the result, it is determined whether or not the route can be set. If the route can be set, the route is set based on the calculation result. If the route cannot be set, the route is calculated again and the O-
It is also possible to realize the function of setting the path of the LSP.

Alternatively, as the setting function, the O-LSP is provided in the node requesting the setting of the E-LSP.
A function for transmitting a path setting request of the LSP, and the O-LS
The O-LSP is provided in a node capable of setting P and the path of the O-LSP is calculated based on the path setting request.
Is set, and the result is notified to the means for transmitting the path setting request, and if the setting is possible, the O
It is also possible to realize the function of setting the LSP.

In this case, for example, as a function of transmitting the path setting request, a node having the smallest number of hops from the own node or the total link cost is selected as a node capable of setting the O-LSP. It is desirable to realize the function of sending a path setting request.

Alternatively, as the setting function, the O-LSP is provided in the node requesting the setting of the E-LSP.
A function for transmitting a path setting request of the LSP, and the O-LS
The O-LSP is provided in a node capable of setting P and the path of the O-LSP is calculated based on the path setting request.
Setting notification by means of a plurality of nodes as a function of transmitting the path setting request by realizing the function of notifying whether the setting is possible and notifying the result to the means for transmitting the path setting request. If multiple nodes arrive, the node that has sent the settable notification will arrive at the node with the earliest settable notification or the node with the smallest number of hops or total link cost from its own node. It is also possible to realize the function of requesting the setting of the O-LSP.

A fourth 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, each node calculates an optimum route and automatically sets the O-LSP and E-LSP by using an information processing device such as a computer device, thereby achieving efficient operation. It is possible to realize a multi-layer optical network and node capable of performing the above.

A fifth aspect of the present invention is a path setting method applied to the multi-layer optical network of the present invention, which is characterized in that the above-mentioned E-LSP is requested in response to the setting request. The O-LSP route is automatically set in consideration of route information including route cost, resource consumption, and traffic volume.

A node requesting the setting of the E-LSP may calculate the path of the O-LSP, and a node on the originating side of the O-LSP may set the path of the O-LSP based on the calculation result. desirable.

Alternatively, the node requesting the setting of the E-LSP calculates the path of the O-LSP and sends a path setting request based on the calculation result, and the node on the originating side of the O-LSP sends the path. After receiving the setting request, it is determined whether or not the route setting based on the calculation result included in the path setting request is possible. If the setting is possible, the route is set based on the calculation result. If the setting is not possible, the route is calculated again. The O
-It is also possible to set the LSP route.

Alternatively, the node requesting the setting of the E-LSP transmits the path setting request of the O-LSP,
The node that can set the O-LSP calculates the route of the O-LSP based on the path setting request, and
It is also possible to determine whether or not the SP can be set, notify the result to the node that has sent the path setting request, and set the O-LSP if it can be set.

At this time, for example, it is desirable to select the node having the smallest number of hops from the own node or the total cost of the link as a node capable of setting the O-LSP, and send the path setting request.

Alternatively, the O-LSP path setting request is transmitted from the node requesting the E-LSP setting,
The node that can set the O-LSP calculates the route of the O-LSP based on the path setting request, and
If the SP setting availability is determined, the result is notified to the node that sent the path setting request, and if the node receives a plurality of settable notifications from a plurality of nodes, the node that sent the settable notification is It is also possible to actually request the setting of the O-LSP from the node having the earliest arrival of the settable notification or the node having the smallest number of hops or the total link cost from the own node.

[0037]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A multi-layer optical network according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is an overall configuration diagram of a multi-layer optical network of this embodiment.

In this embodiment, as shown in FIG. 1, a plurality of sub-networks 9 to 11 for switching and transferring in packet units and an optical path OP1 which is an O-LSP connecting the sub-networks 9 to 11 are connected. To OP3 and nodes 1 to 3 terminating the optical paths OP1 to OP3,
Nodes having PSCs capable of switching in packet units in addition to nodes 1 to 3 being LSCs capable of switching in optical wavelength units at both ends of an optical wavelength link configured by optical paths OP1 to OP3 and nodes 1 to 3. Border routers 4 to 8 are respectively provided, and thus, optical paths OP1 to O that are O-LSPs having nodes 1 to 3 at both ends are provided.
P3 and an electrical path EP1 which is an E-LSP including the optical paths OP1 to OP3 and having border routers 4 to 8 at both ends.
~ EP3 is a multi-layer optical network having a two-layer structure.

Here, the feature of this embodiment is that
The nodes 1 to 3 automatically set the routes of the optical paths OP1 to OP3 in consideration of the route information including the route cost, the resource consumption, and the traffic amount in response to the setting request of the electrical paths EP1 to EP3 of the border routers 4 to 8. There is a place to do it.

As described above, in the multi-layer optical network of the present embodiment, it is possible to set the necessary path in consideration of the route information including the route cost, the resource consumption, and the traffic amount when the generated traffic is taken as an opportunity, so that it is efficient. Network operation can be performed.

In the first embodiment, the border routers 4 to 8 calculate the routes of the optical paths OP1 to OP3, and the nodes 1 to 3
The paths of the optical paths OP1 to OP3 are set based on the calculation result.

As a result, the border routers 4 to 8 can also set the paths of the optical paths OP1 to OP3.
Therefore, the users who use the border routers 4 to 8 are
Since even the route setting of the optical paths OP1 to OP3 included therein can be performed according to the request, it is possible to improve the convenience of the user and the network operator can use the optical paths OP1 to OP3. Since it is not necessary to set the route by itself, and moreover, the optimum route setting of the optical paths OP1 to OP3 according to the traffic condition of the electric paths EP1 to EP3 is performed, the labor of the route setting of the optical paths OP1 to OP3 is saved. In addition, the multi-layer optical network can be operated efficiently.

In the second embodiment, the border routers 4 to 8 calculate the routes of the optical paths OP1 to OP3 and send out the path setting request based on the calculation result, and the nodes 1 to 3 receive the path setting request. After that, whether or not the route setting is possible based on the calculation result included in the path setting request is determined, and if the setting is possible, the route is set based on the calculation result, and if the setting is not possible, the route is calculated again to calculate the optical path OP1. ~ Set the route of OP3.

According to this, when the routes of the optical paths OP1 to OP3 are frequently updated, the border routers 4 to 8 calculate the routes of the optical paths OP1 to OP3 and send the path setting request. , There is a time lag between the time when this path setting request arrives at the nodes 1 to 3 and the nodes 1 to 3 actually set the paths of the optical paths OP1 to OP3, and during that time, the traffic of the optical paths OP1 to OP3. It is also possible to deal with cases where the situation changes.

In the third embodiment, the border routers 4 to 8 send path setting requests for the optical paths OP1 to OP3, and the node 1
3 to 3 are optical paths OP1 to OP based on the path setting request.
No. 3 is calculated, the propriety of setting the optical paths OP1 to OP3 is determined, the result is notified to the border routers 4 to 8, and if the setting is possible, the O-LSP is set.

At this time, the border routers 4 to 8 are the nodes 1 to 3 in which the optical paths OP1 to OP3 can be set, and the node i (i is 1 to 1) having the smallest hop count or link total cost from its own border router. 3) is selected and a path setting request is transmitted.

According to this, the border routers 4 to 8 are
The route calculation of P1 to OP3 is not performed and the route is not set, and the route calculation of OP1 to OP3 is entrusted to the nodes 1 to 3. This reduces the load on the border routers 4-8. However, the border routers 4 to 8 can make a path setting request for the optical paths OP1 to OP3 to the nodes 1 to 3, and at that time, the border routers 4 to 8 will select the node i that is most convenient for their own border router. Can be selected. As a result, the path and the light wavelength can be secured with high probability.

In the fourth embodiment, the border routers 4-8 are
The nodes 1 to 3 send out path setting requests for the optical paths OP1 to OP3, and the optical paths OP1 to O based on the path setting requests.
P3 route calculation is performed to determine whether or not the optical paths OP1 to OP3 can be set, and the result is notified to the border routers 4 to 8. The border routers 4 to 8 receive a plurality of settable notifications from the plurality of nodes 1 to 3. When it arrives, from among the nodes 1 to 3 that have sent the settable notification, the node i that has received the settable notification earliest or the node i with the smallest hop count or link total cost from its own border router On the other hand, the actual setting of the optical path OPi is requested.

According to this, the border routers 4 to 8 do not calculate the routes of the optical paths OP1 to OP3 and do not set the routes, and the route calculation of the optical paths OP1 to OP3 is performed by the node 1 Entrust to ~ 3. This reduces the load on the border routers 4-8. However, the border routers 4 to 8 send the optical paths OP1 to OP3 to the plurality of nodes 1 to 3.
Path setting request can be made, and at that time, the border routers 4 to 8 can select the most convenient node i for the own border router from among the settable notifications from the plurality of nodes 1 to 3. it can. The most convenient node i is, for example, the node i from which the settable notification arrives earliest or the node i having the smallest number of hops or the total link cost from the own border router. As a result, the path and the light wavelength can be secured with high probability.

The nodes 1 to 3 and the border routers 4 to 8 of this embodiment can be realized by using a computer device which is an information processing device. That is, a program which, when installed in a computer device, causes the computer device to realize the functions corresponding to the nodes 1 to 3 and the border routers 4 to 8 applied to the multilayer optical network of the present embodiment, Pass EP1
By installing a program in a computer device that realizes a function of automatically setting routes of the optical paths OP1 to OP3 in consideration of route information including route cost, resource consumption, and traffic volume in response to a setting request of EP3 to EP3 , The computer device as nodes 1 to 3 of this embodiment.
And a device corresponding to the border routers 4-8.

As the function to be set, the border router 4
To 8 for calculating the paths of the optical paths OP1 to OP3 and a function for realizing the functions of the nodes 1 to 3 for setting the paths of the optical paths OP1 to OP3 based on the calculation result of the calculating function. Is installed in the computer device, the computer device can be a device corresponding to the nodes 1 to 3 and the border routers 4 to 8 of the first embodiment.

Alternatively, as the setting function, a function is provided in the border routers 4 to 8 to calculate routes of the optical paths OP1 to OP3 and to send a path setting request based on the calculation result. After receiving the path setting request, it is determined whether or not the path setting based on the calculation result included in the path setting request is possible. If the setting is possible, the path is set based on the calculation result. By installing a program for realizing the function of calculating and setting the paths of the optical paths OP1 to OP3 in the computer device, the control device corresponds to the nodes 1 to 3 and the border routers 4 to 8 of the second embodiment. It can be a device.

Alternatively, as the function to be set, a function is provided in the border routers 4 to 8 to send a path setting request for the optical paths OP1 to OP3, and an optical path OP1 is provided in the nodes 1 to 3 based on the path setting request. ~ OP3 path calculation is performed to determine whether or not the optical paths OP1 to OP3 can be set, the result is notified to the border routers 4 to 8, and if the setting is possible, a function of setting the optical paths OP1 to OP3 is realized. Further, as a function of transmitting the path setting request, a program for realizing a function of transmitting a path setting request by selecting a node i having the smallest hop count or total link cost from the own border routers as the nodes 1 to 3 is provided. By installing on a computer device,
The computer device can be a device corresponding to the nodes 1 to 3 and 4 to 8 of the third embodiment.

Alternatively, as the function to be set, a function is provided in the border routers 4 to 8 to send a path setting request for the optical paths OP1 to OP3, and an optical path OP1 is provided in the nodes 1 to 3 based on the path setting request. To OP3, a function of determining whether or not the optical paths OP1 to OP3 can be set and notifying the results to the border routers 4 to 8 is realized, and a plurality of nodes 1 are provided as a function of transmitting the path setting request. When a plurality of settable notifications from the notification function have arrived from the node i or the own border router from which the settable notification arrives earliest among the nodes 1 to 3 which sent the settable notifications. Of the program that implements the function of actually requesting the setting of the optical path OPi to the node i with the smallest total hop count or total link cost. By installing the Yuta device, the node 1 and the computer device of the fourth embodiment
~ 3 and border routers 4-8.

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

Thus, using the computer device,
A multi-layer optical network and node capable of achieving efficient operation by each node 1 to 3 and border routers 4 to 8 of the O-LSP and the E-LSP calculating and automatically setting optimum routes Can be realized.

The present embodiment will be described in more detail below. In the following, in order to make the explanation easier to understand,
The description will be given in the form of extracting a part of the multilayer optical network shown in FIG.

(First Embodiment) A first embodiment will be described with reference to FIG. 1, 2, 3 are nodes of the multilayer optical network, 4, 5, 6, 7, and 8 are border routers of the sub-network, and OP1, OP2, and OP3 are optical paths (OL).
SP), EP1, EP2, EP3 are electrical paths (E-LS
P), 9, 10 and 11 are sub-networks. The border router 4 and the border router 5 are set with an electrical path EP1 using the optical path OP1. In addition, the border router 6 and the border router 7 are electric paths EP using the optical path OP2.
2 is set.

When AC traffic is newly generated between the border router 8 and the border router 7, the border router 8 sends the node 1 an E-connection with the border router 7.
Request LSP settings. Since the node 1 does not have an O-LSP with the node 3, it is possible to set the border router 7 and the E-LSP via the node 2, and a new optical path OP3 is directly provided with the node 3. Can also be set to set the electrical path EP3. Which setting is optimal depends on the judgment of the node 1.

(Second Embodiment) A second embodiment will be described with reference to FIG. FIG. 2 is a diagram for explaining the O-LSP setting procedure of the second embodiment. 12, 13, and 14 are nodes having both PSC and LSC and capable of terminating O-LSP, R1 is an O-LSP routing signal,
OP4 is an O-LSP. Node 12 is now E-LS
As a result of the route calculation of P, node 14 is passed through node 13.
When the E-LSP using the is set, the node 12 has the node 12 and the node 14 with respect to the node 13.
Signal R instructing to use the optical path OP4 between
1 and the node 13 uses the optical path OP4 to perform E-
Set LSP.

(Third Embodiment) A third embodiment will be described with reference to FIG. FIG. 3 is a diagram for explaining the O-LSP setting procedure of the third embodiment. R2 is an O-LSP setting instruction signal. Now, when the node 12 decides to set the E-LSP via the node 13 as a result of the E-LSP route calculation, the node 12 instructs the node 13 to transmit the optical signal between the node 12 and the node 14. The signal R2 designated to set the path OP4 is transmitted. At node 13,
The route is calculated again, and the optical path OP4 is set between the node 14 and the node 14 which seems to be optimal.

(Fourth Embodiment) A fourth embodiment will be described with reference to FIG. FIG. 4 is a diagram for explaining the O-LSP setting procedure of the fourth embodiment. 15 is a node that has both PSC and LSC like other nodes and can terminate O-LSP, R3 is an O-LSP setting request signal, and A3 is an O-LSP setting availability notification signal.

The node 12 calculates the route for constructing the E-LSP and has the ability to set the O-LSP.
To the next node, a signal R3 requesting the setting of the O-LSP with the next node is transmitted. The node 13 checks whether the O-LSP can be set based on the signal R3, and if possible, O
-The LSP is set and the signal A3 including the content indicating that the setting is possible is returned to the node 12, but the O-LS designated by the signal R3 is returned.
If the setting of P is impossible, the signal A3 including the content indicating that the setting is impossible is returned. The node 12 looks at the returned signal, and if the signal A3 from the node 13 indicates that the setting is impossible, the route calculation is performed again and the node 14 is requested to set the O-LSP. Signal R3 for transmitting. If a signal indicating that the O-LSP cannot be set is returned from the node 14, then an O-LSP setting request signal is transmitted to the node 15. The node 12 repeats this operation until the E-LSP path can be configured. Node 12 is OL
The order of the partner node transmitting the SP setting request is E-LS.
As a result of the route calculation of P, it is performed in the ascending order of the number of hops when setting the O-LSP and in the ascending order of the total cost.

(Fifth Embodiment) A fifth embodiment will be described with reference to FIG. FIG. 5 is a diagram for explaining the O-LSP setting procedure of the fifth embodiment. R41, R42 and R43 are O
-LSP route calculation request signal, A41, A42, A43 are O-LSP route calculation result signals. Node 12 is E
-In constructing the LSP, for the time being O-LSP
The O-LSP route calculation request signal is simultaneously transmitted to all the nodes having the setting capability of.

The nodes that have received the O-LSP route calculation request signal respectively perform O-LSP route calculation, and put the result in the O-LSP route calculation result signal and send it back to the node 12. In the node 12, among the returned O-LSP route calculation result signals, the node that returned the O-LSP route calculation result signal earliest or the most cost among the nodes that returned the contents of the O-LSP setting possible Is adopted, the result of either the node calculated to be small or the node calculated to have the smallest number of hops is adopted, and an O-LSP setting instruction is given to that node.

[0066]

As described above, according to the present invention,
Each node calculates an optimum route and automatically sets the O-LSP and E-LSP, so that efficient operation can be achieved.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a multilayer optical network according to an embodiment.

FIG. 2 is a diagram for explaining an O-LSP setting procedure according to the first embodiment.

FIG. 3 is a diagram for explaining an O-LSP setting procedure according to the second embodiment.

FIG. 4 is a diagram for explaining an O-LSP setting procedure according to the third embodiment.

FIG. 5 is a diagram for explaining an O-LSP setting procedure according to the fourth embodiment.

[Explanation of symbols]

1-3, 12-15 nodes 4-8 border router 9-11 sub-network OP1-OP4 Optical path (O-LSP) EP1 to EP3 electric path (E-LSP) R1 to R3 O-LSP route instruction signal A3 O-LSP setting availability notification signal R41 to R43 O-LSP route calculation request signal A41 to A43 O-LSP route calculation result signal

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kohei Shiomoto             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Ya Imajuku             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Naoaki Yamanaka             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F term (reference) 5K030 GA14 HA08 HC20 JL03 KA05                       LB05 MD07

Claims (18)

[Claims] 1. A plurality of sub-networks for performing packet-by-packet switching and transfer, an optical transmission line connecting the sub-networks, and a node terminating the optical transmission line, the optical transmission line and the node Optical wavelength switching capability (LSC) capable of switching in optical wavelength units and packet switching capability (PSC) capable of switching in packet units are provided at both ends of the optical wavelength link configured by In a multi-layer optical network having a two-layer structure of an optical wavelength link (referred to as O-LSP) provided and a packet link (referred to as E-LSP) including the O-LSP and having PSCs at both ends, the E -Route cost, resource consumption, and traffic of the O-LSP route in response to the LSP setting request. A multi-layer optical network, which is provided with a means for automatically setting it in consideration of route information including a traffic amount. 2. The means for setting is provided in a node requesting the setting of the E-LSP, and means for calculating a route of the O-LSP, and the calculation means provided in a node on the originating side of the O-LSP. The multi-layer optical network according to claim 1, further comprising means for setting a path of the O-LSP based on a calculation result of the means for performing. 3. The means for setting is provided in a node requesting the setting of the E-LSP, calculates a path of the O-LSP, and sends a path setting request based on the calculation result, -Providing a route provided based on the calculation result included in the path setting request after receiving the path setting request provided in the node on the originating side of the LSP, and setting the route based on the calculation result if the setting is possible. The multi-layer optical network according to claim 1, further comprising means for calculating a route and setting the route of the O-LSP again if the route cannot be set. 4. The means for setting is provided in a node requesting the setting of the E-LSP, and transmitting the path setting request of the O-LSP, and provided in the node capable of setting the O-LSP. Based on the path setting request, the route of the O-LSP is calculated, whether or not the setting of the O-LSP is possible is determined, and the result is notified to the means for transmitting the path setting request. The multi-layer optical network according to claim 1, further comprising means for setting an LSP. 5. The means for transmitting the path setting request selects a node having the smallest number of hops from the own node or the total cost of links as a node capable of setting the O-LSP, and transmits the path setting request. The multi-layer optical network according to claim 4, further comprising: 6. The means for setting is provided in a node requesting the setting of the E-LSP, and transmitting the path setting request of the O-LSP, and provided in the node capable of setting the O-LSP. The path setting request, the path calculation of the O-LSP is performed based on the path setting request, the possibility of setting the O-LSP is determined, and the result is notified to the means for sending the path setting request. When a plurality of settable notifications by the notifying means from a plurality of nodes have arrived, the means for sending the O-LS is actually applied to the node with the smallest number of hops from the node or the total cost of the link.
The multilayer optical network according to claim 1, further comprising means for requesting setting of P. 7. The node applied to the multi-layer optical network according to claim 1, wherein the route information of the O-LSP includes a route cost, resource consumption, and a traffic amount in response to a request for setting the E-LSP. A node characterized by having means for automatically setting in consideration of. 8. The means for setting is provided in a node requesting the setting of the E-LSP to calculate a route of the O-LSP, and the calculation means provided in a node on the originating side of the O-LSP. 8. The node according to claim 7, further comprising means for setting a path of the O-LSP based on a calculation result of the means for performing. 9. The setting means is provided in a node requesting the setting of the E-LSP, calculates a path of the O-LSP, and sends a path setting request based on the calculation result, -Providing a route provided based on the calculation result included in the path setting request after receiving the path setting request provided in the node on the originating side of the LSP, and setting the route based on the calculation result if the setting is possible. The node according to claim 7, further comprising means for calculating a route and setting the route of the O-LSP if the setting is impossible. 10. The means for setting is provided in a node requesting the setting of the E-LSP, and transmitting the path setting request of the O-LSP, and provided in the node capable of setting the O-LSP. Based on the path setting request, the route of the O-LSP is calculated, whether or not the setting of the O-LSP is possible is determined, and the result is notified to the means for transmitting the path setting request. A node according to claim 7, comprising means for setting an LSP. 11. The means for transmitting the path setting request comprises:
11. The node according to claim 10, further comprising means for selecting a node having the smallest number of hops from the own node or the total cost of links as a node capable of setting the O-LSP and transmitting a path setting request. 12. The means for setting is provided in a node requesting the setting of the E-LSP, and transmitting the path setting request of the O-LSP, and provided in the node capable of setting the O-LSP. The path setting request, the path calculation of the O-LSP is performed based on the path setting request, the possibility of setting the O-LSP is determined, and the result is notified to the means for sending the path setting request. When a plurality of settable notifications by the notifying means from a plurality of nodes have arrived, the means for sending the O-LS is actually applied to the node with the smallest number of hops from the node or the total cost of the link.
8. The node according to claim 7, comprising means for requesting the setting of P. 13. The path setting method applied to a multilayer optical network according to claim 1, wherein a path cost, resource consumption, and a traffic amount are included in a path of the O-LSP in response to a setting request of the E-LSP. A path setting method characterized by being set automatically in consideration of route information. 14. The node requesting the setting of the E-LSP calculates the path of the O-LSP, and the node on the originating side of the O-LSP sets the path of the O-LSP based on the calculation result. The path setting method according to claim 13. 15. A node requesting the setting of the E-LSP calculates a path of the O-LSP, sends a path setting request based on the calculation result, and the node on the originating side of the O-LSP sends the path. After receiving the setting request, it is determined whether or not the route setting based on the calculation result included in the path setting request is possible. If the setting is possible, the route is set based on the calculation result. If the setting is not possible, the route is calculated again. The route of the O-LSP is set.
The path setting method described in 3. 16. A node that requests the setting of the E-LSP sends a path setting request of the O-LSP, and a node capable of setting the O-LSP sets the O-LSP based on the path setting request. The route is calculated and the OL
14. The path setting method according to claim 13, wherein whether or not the SP can be set is determined, the result is notified to the node that has sent the path setting request, and if the setting is possible, the O-LSP is set. 17. The path setting method according to claim 16, wherein a node having the smallest number of hops from the own node or the total link cost is selected as a node capable of setting the O-LSP, and the path setting request is transmitted. 18. The O-LSP path setting request is transmitted from the node requesting the E-LSP setting, and the node capable of setting the O-LSP sets the O-LSP setting request based on the path setting request. The route is calculated and the OL
When the SP setting availability is determined, the result is notified to the node that sent the path setting request, and if the node receives a plurality of settable notifications from a plurality of nodes, the node that sent the settable notification is notified. 14. The path setting method according to claim 13, wherein an O-LSP setting is actually requested from the node having the earliest arrival of the settable notification or the node having the smallest hop number or total link cost from the nodes.