JP3785100B2 - Optical IP communication network and node - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a node used in an optical IP communication network and an optical IP communication network configured using the node.
[0002]
[Prior art]
〔node〕
FIG. 9 shows classifications of various nodes used in the optical IP communication network and switching capabilities (SC) set in the interfaces of these nodes. 9A is a type I node using an IP router (electric router), FIG. 9B is a type II node using a wavelength router, and FIG. 9C is an IP router and a wavelength router. Type III node.
[0003]
The type I node 1 includes the IP router 1-1 as a component, and has interfaces I1, I2, O1, and O2. The type II node 2 has the wavelength router 2-1 as its component and has interfaces I1, I2, O1, and O2. Type III node 3 has IP router 3-1 and wavelength router 3-2 as its components, and has interfaces I 1, I 2, I 3, O 1, O 2, and O 3 on the side of wavelength router 3-2. -1 side has interfaces I4 and O4.
[0004]
In FIG. 9, the interface is indicated by a black circle. Each interface is assigned an ID (identification number) as unique information for identifying it in the communication network. An example of the ID is an IP address.
[0005]
In FIG. 9A, the interfaces I1, I2, O1, and O2 of the node 1 all have PSC (Packet Switching Capability). PSC refers to switching capability that is exchanged for each packet.
[0006]
In FIG. 9B, the interfaces I1, I2, O1, and O2 of the node 2 all have LSC (Lambda Switching Capability). LSC refers to switching capability that is exchanged for each wavelength. Here, in FIG. 9B, the description of the physical optical fiber is omitted. A plurality of interfaces having LSCs belong to one optical fiber port, but logically, interfaces are defined for each wavelength in the communication network.
[0007]
In FIG. 9C, the interfaces I1, I2, I3, O1, O2, and O3 on the wavelength router 3-2 side of the node 3 have PSC and LSC switching capabilities. That is, the interfaces 1, I2, I3, O1, O2, and O3 on the wavelength router 3-2 side in the node 3 can be either LSC or PSC in a connection form by switching. The switching capability of the interface in such a case is expressed as “PSC + LSC” in FIG. 9C. In FIG. 9C, the interfaces I4 and O4 on the IP router 3-1 side of the node 3 are PSCs because they are always exchanged by the IP router 3-1.
[0008]
[Optical IP communication network]
FIG. 10 shows an example of an optical IP communication network using type I, II, and III nodes. In the figure, nodes A, E, and F are type I nodes, nodes B, D, and G are type II nodes, and node C is a type III node. The optical path # 1 is between the IP router A1 of the node A and the IP router C1 of the node C, and the optical path # 2 is between the IP router C1 of the node C and the IP router F1 of the node F. An optical path # 3 is set between the IP router C1 of the node E and the IP router E1 of the node E.
[0009]
The optical path # 1 is terminated by IP routers A1 and C1, the optical path # 2 is terminated by IP routers C1 and F1, and the optical path # 3 is terminated by IP routers C1 and E1. In the wavelength routers B1, D1, and G1 of the nodes B, D, and G, the optical paths # 1, # 2, and # 3 are not terminated, and only switching in units of wavelengths is performed. In FIG. 10, PF1 to PF4 are optical fibers.
[0010]
FIG. 11 shows a schematic configuration of a conventional type III node 3. The node 3 is provided with a control unit CNT. The control unit CNT includes a flooding unit BL1, a link state DB / BL2, a route calculation unit BL3, and a path setting unit BL4. The unique switching capability of the interfaces I1, I2, I3, I4, O1, O2, O3, and O4 of the node 3 is stored in the link state DB · BL2, and OSPF (open show test path · Using a routing protocol such as (finding), advertisement is made to other nodes in the optical IP communication network via the flooding unit BL1.
[0011]
Other nodes also have the same control unit CNT as the node 3 and advertise the unique switching capability of the interface in the own node in the same manner as the node 3. In the node 3, the switching capability of the interface advertised from the upstream node is taken into the link state DB / BL2 via the flooding unit BL1 and sent to the downstream node. Nodes in the communication network are connected in a ring shape by a control path.
[0012]
As a result, the link state DB · BL2 of the node 3 stores the unique switching capability of each interface of the node as link state information for all nodes in the optical IP communication network. Similarly to the node 3, the link state DB / BL2 in the other nodes also includes the unique switching capability of each interface of the node in the optical IP communication network. Is remembered as
[0013]
In the node 3, the route calculation unit BL3 calculates a route from the source node to the destination node with reference to the link state information stored in the link state DB / BL2, and sends the calculated route to the path setting unit BL4. . The path setting unit BL4 sets a path to the IP router 3-1 and the wavelength router 3-2 based on the route from the route calculation unit BL3, and routes the route from the route calculation unit BL3 to the upstream node and the downstream node. Inform. In the upstream node and the downstream node, a path in the own node is set according to a route known from the node 3.
[0014]
As for advertisement of switching capability using routing protocol such as OSPF, Reference 1 (J.Moy, “OSPF Version 2,” RFC2328, 1998.), Reference 2 (R. Coltun, “The OSPF Opaque LSA Option, "RFC2370, 1998.", Reference 3 (A. Banerjee, J. Drake, JPLang, B. Turner, K. Kompella, and Y. Rekhter, "Generalized Multiprotocol Label Switching: An Overview of Routing and Management Enhacements," IEEE Commun. Mag., Pp. 144-150, Jan. 2001).
[0015]
[Optical path setting example 1 in an optical IP communication network]
FIG. 12 shows an example of setting an optical path in the optical IP communication network. In this example, the nodes H and K are type I nodes, the node J is a type II node, the source node is the node H, the destination node is the node K, and the path calculation is performed in the control unit CNT of the node H. Is sent to the nodes J and K via the control paths S1 and S2, so that between the node H and the node K, from the interface O2 of the node H to the node K via the interfaces I2 and O1 of the node J. The optical path # 1 leading to the interface I1 is set.
[0016]
In the example of FIG. 12, when setting the optical path # 1, the interface I2 and O1 of the node J are connected using the LSC. As a result, the interfaces I2 and O1 have no usable switching capability. That is, no usable switching capability is left in the interfaces I2 and O1. The state in which this switching capability is not left is called “Nothing”.
[0017]
[Example 2 of setting optical path in optical IP communication network]
FIG. 13 shows another setting example of the optical path in the optical IP communication network. In this example, the nodes L, M, and N are type III nodes, the source node is the node L, the destination node is the node M, the route calculation is performed in the control unit CNT of the node L, and the calculated route is the control path S1. To the node M, the optical paths # 1 and # 2 are set between the node L and the node M.
[0018]
That is, the output port P of the IP router L1 of the node L _out1 Through the interface O1 of the wavelength router L2 of the node L, the interface I1 of the wavelength router M2 of the node M, and the input port P of the IP router M1 of the node M _in1 And the output port P of the IP router L1 of the node L _out2 Through the interface O3 of the wavelength router L2 of the node L, the interface I3 of the wavelength router M2 of the node M, and the input port P of the IP router M1 of the node M _in2 Optical path # 2 leading to is set.
[0019]
Further, with the source node as M and the destination node as a downstream node not shown in the figure, the control unit CNT of the node M performs route calculation, and sends the calculated route to the node N via the control path S2, whereby the node Optical path # 3 is set between M and node N. That is, the output port P of the IP router M1 of the node M _out1 Then, the optical path # 3 that enters the interface I3 of the wavelength router N2 of the node N through the interface O3 of the wavelength router M2 of the node M and exits from the interface O3 of the wavelength router N2 is set.
[0020]
In the example of FIG. 13, when setting the optical path # 1, the interface O1 of the wavelength router L2 in the node L is changed to the output port P of the IP router L1. _out1 And the interface I1 of the wavelength router M2 at the node M is connected to the input port P of the IP router M1. _in1 Are connected using LSC.
[0021]
In setting the optical path # 2, the interface O3 of the wavelength router L2 in the node L is connected to the output port P of the IP router L1. _out2 And the interface I3 of the wavelength router M2 at the node M is connected to the input port P of the IP router M1. _in2 Are connected using LSC.
[0022]
In setting the optical path # 3, the interface O3 of the wavelength router M2 in the node M is connected to the output port P of the IP router M1. _out1 Are connected using the LSC, and the interfaces I3 and O3 of the wavelength router N2 in the node N are connected using the LSC.
[0023]
As a result, the interfaces O1 and O3 of the node L and the interfaces I1, I3 and O3 of the node M have no LSC as switching capability, and only the PSC remains. Further, the interfaces I3 and O3 of the node N are both “Nothing” because both LSC and PSC disappear. Note that the PSC, which is a switching capability that is exchanged for each packet, is left when the interface is terminated at the IP router, and is not terminated at the IP router like the interfaces I3 and O3 of the node N. The ability is lost when relaying optical paths.
[0024]
[Problems to be solved by the invention]
As described above, the switching capability of the interface varies depending on the usage status of resources (interfaces and input / output ports) in the node. However, in the conventional technology, the usage status of the resources in the node is not reflected in the switching capability of the advertised interface. For this reason, there is a possibility that an appropriate path cannot be selected when calculating the path of the optical path. Further, there is a possibility that an appropriate optical path cannot be set when setting the optical path.
[0025]
For example, in the example of FIG. 12, the interfaces I2 and O1 of the node J are stored in the own node assuming that the switching capability is LSC. Moreover, it is advertised to other nodes H and K that the switching capability is LSC. However, since the optical path # 1 is set, the switching capability of the interface I2 and O1 of the node J becomes “Nothing”. In this case, the switching capability of the interfaces I2 and O1 of the node J is kept LSC in the link state information of the nodes H, J, and K. For this reason, there is a possibility that a problem may occur that an appropriate path cannot be selected during route calculation, or that an appropriate optical path cannot be set when setting an optical path.
[0026]
In the example of FIG. 13, the interfaces O1 and O3 of the node L are stored in the own node assuming that the switching capability is “PSC + LSC”. Further, it is advertised to other nodes M and N that the switching capability is “PSC + LSC”. Further, the interfaces I1, I3, and O3 of the node M are stored in the own node assuming that the switching capability is “PSC + LSC”. Further, it is advertised to other nodes L and N that the switching capability is “PSC + LSC”. Further, the interfaces I3 and O3 of the node N are stored in the own node assuming that the switching capability is “PSC + LSC”. Further, it is advertised to other nodes L and M that the switching capability is “PSC + LSC”.
[0027]
However, since the optical paths # 1, # 2, and # 3 are set, the switching capabilities of the interfaces O1 and O3 of the node L and the interfaces I1, I3, and O3 of the node M remain only PSC, and the interface I3 of the node N , O3 has a switching capacity of “Nothing”. In this case, the switching capabilities of the interfaces O1, O3 of the node L, the interfaces I1, I3, O3 of the node M, and the interfaces I3, O3 of the node N remain “PSC + LSC” in the link status information of the nodes L, M, and N. It is said. For this reason, there is a possibility that a problem may occur that an appropriate path cannot be selected during route calculation, or that an appropriate optical path cannot be set when setting an optical path.
[0028]
The present invention has been made to solve such a problem, and the object of the present invention is to perform more accurate route calculation and advertisement by advertising the switching capability of the interface reflecting the resource usage status of the node. An object is to provide an optical IP communication network and a node capable of setting a path.
[0029]
[Means for Solving the Problems]
In order to achieve such an object, the present invention includes a node (type I node) having an interface having a switching capability to be exchanged for each packet, and an interface having a switching capability to be exchanged for each wavelength. Node (type III node), an interface having an interface that can be any of an interface having a switching capability to be exchanged for each packet and an interface having a switching capability to be exchanged for each wavelength (type III) In the optical IP communication network configured using at least one of the nodes of the node, the nodes (type I, II, and III nodes) are connected to the interfaces in the own node based on the resource usage status in the own node. Determine the current switching capability and use this interface The current switching capability of the face is provided with a switching capability advertisement means for advertising the other nodes with updating stored in the own node (the first invention).
[0030]
In the first invention, the node in the optical IP communication network determines the current switching capability of the interface in the own node based on the usage status of the resource in the own node, and sets the current switching capability of the interface to the own node. Update and store and advertise to other nodes. For example, in a type III node, when the current switching capability of an interface changes from “PSC + LSC” to “PSC”, the switching capability of the interface is updated and stored in the own node as “PSC” and is advertised to other nodes. .
[0031]
In addition, the present invention provides a node (type I node) having an interface having a switching capability to be exchanged for each packet, and a node (type II node) having an interface having a switching capability to be exchanged for each wavelength. ), At least one of nodes (type III nodes) having an interface that can be either an interface having a switching capability to be exchanged for each packet or an interface having a switching capability to be exchanged for each wavelength. In the optical IP communication network configured using the network, the node (type I, II, III) determines the current switching capability of the interface in the own node based on the usage status of the resource in the own node. , The current switch for this interface Is provided with a switching capability advertisement means for advertising with the other node to the self node to the updated and stored as a pair and a unique switching capabilities that are inherently possessed a ring capability (second invention).
[0032]
In the second invention, the node in the optical IP communication network determines the current switching capability of the interface in the own node based on the usage status of the resource in the own node, and inherently has the current switching capability of the interface. As a pair, the unique switching capability is updated and stored in its own node and advertised to other nodes. For example, in a type III node, if the current switching capability of an interface having “PSC + LSC” as the inherent switching capability is changed to “PSC”, the current switching capability (dynamic switching capability) is changed to “PSC”. The inherent switching capability (static switching capability) possessed is “PSC + LSC”, and the dynamic switching capability “PSC” and the static switching capability “PSC + LSC” are paired and stored in the own node. And advertise to other nodes.
[0033]
In the present invention (first invention, second invention), the usage status of the resource in the own node in the switching capability advertising means is the usage status of the interface in the own node (third invention) or the use of the interface in the own node. The status and the usage status of resources other than the interface in the own node (fourth invention) are included. The usage status of resources other than the interface in the own node is, for example, the usage status of the input / output port of the IP router.
[0034]
In the first invention, the switching capability advertising means updates and stores the current switching capability of the interface in its own node and advertises it to other nodes. In this case, the interface does not always have the switching capability, and there are interfaces that do not have the switching capability. For an interface that does not have switching capability, information indicating that the switching capability is not left is updated and stored in its own node and advertised to other nodes as the current switching capability of the interface (fifth invention).
For example, when a type III node loses the switching capability of an interface, “Nothing” is updated and stored in the own node as the switching capability of the interface and is advertised to other nodes.
[0035]
In the second invention, the switching capability advertising means updates and stores the current switching capability of the interface and the inherent switching capability inherent in the interface as a pair and advertises it to other nodes. In this case, the interface does not always have the switching capability, and there are interfaces that do not have the switching capability. For an interface that does not have switching capability left, information indicating that no switching capability is left as the current switching capability of the interface is updated and stored in its own node as a pair with the inherent switching capability. Advertise to the node (sixth invention).
For example, in a type III node, when the switching capability of an interface whose inherent switching capability is “PSC + LSC” disappears, pair “Nothing” with “PSC + LSC” as the switching capability of the interface, Update and store in the own node and advertise to other nodes.
[0036]
If there is an interface that does not have switching capability, information indicating that the switching capability is not left is not sent, but the unique information (for example, IP address) of the interface is not advertised to other nodes. (7th invention). In this case, it is assumed that the other interface is advertised with the current switching capability and unique information (for example, IP address) of the interface.
[0037]
Further, at least one control path for exchanging routing protocol information is secured between adjacent nodes (eighth invention).
Further, the present invention is effective not only as an optical IP communication network but also as a single node (9th to 12th inventions).
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings.
[Router]
FIG. 1 is a block diagram showing an outline of an embodiment of a node used in an optical IP communication network according to the present invention. In the figure, the same reference numerals as those in FIG. 11 denote the same or equivalent components, and the description thereof will be omitted. In the present embodiment, a switching capability monitoring unit BL5 is provided in the control unit CNT of the node 3.
[0039]
The switching capability monitoring unit BL5 periodically observes the usage status of resources in the node 3 (such as the input / output port of the IP router 3-1 and the interface of the wavelength router 3-2), and based on the observation information, the node 3 The current switching capability of the interfaces I1, I2, I3, I4, O1, O2, O3, O4 is determined, and the current switching capability of the interfaces I1, I2, I3, I4, O1, O2, O3, O4 is determined. The update is stored in the link state DB · BL2.
[0040]
The link state DB / BL2 initially stores the inherent switching capability of the interfaces I1, I2, I3, I4, O1, O2, O3, and O4. For example, when the switching capability is not left in the interface O1, the switching capability monitoring unit BL5 updates “Nothing” indicating that the switching capability is not left to the link state DB · BL2 as the current switching capability. Remember.
[0041]
The current switching capability of the interfaces I1, I2, I3, I4, O1, O2, O3, and O4 in the node 3 updated and stored in the link state DB / BL2 is determined by using a routing protocol such as OSPF. It is advertised to the other nodes through the flooding part BL1. Other nodes also have the same control unit CNT as the node 3, and in the same way as the node 3, the current switching capability of the interface in the own node updated and stored in the link state DB · BL 2 is advertised to the other nodes. To do.
[0042]
Thereby, the current switching capability of each interface in the node is stored as link state information in all the nodes in the optical IP communication network in the link state DB · BL2 of the node 3. Further, in the link state DB · BL2 in other nodes, the current switching capability of each interface in the node is stored as link state information for all nodes in the optical IP communication network in the same manner as the node 3. .
[0043]
In order to exchange routing protocol information, it is necessary to secure at least one control path between adjacent nodes. That is, there is a mechanism for guaranteeing that adjacent nodes can always maintain RA (Routing Adjacency). It is ensured that the interfaces are all “Nothing” so that RA (Routing Adjacency) cannot be established between adjacent nodes. The control path may be established inbound as part of a data link established between adjacent nodes. In that case, the data link must be established at all times. The control path may be established on the outbound side separately from the data link.
[0044]
[Optical path setting example 1 in an optical IP communication network]
FIG. 2 shows an example of setting an optical path in the optical IP communication network. In this example, the nodes H and K are type I nodes, the node J is a type II node, the source node is the node H, the destination node is the node K, and the path calculation is performed in the control unit CNT of the node H. Is sent to the nodes J and K via the control paths S1 and S2, so that between the node H and the node K, from the interface O2 of the node H to the node K via the interfaces I2 and O1 of the node J. The optical path # 1 leading to the interface I1 is set. Note that the nodes H, J, and K have a switching capability monitoring unit BL5 in the control unit CNT, similarly to the node 3 shown in FIG.
[0045]
In the example of FIG. 2, when setting the optical path # 1, the interfaces I2 and O1 of the node J are connected using the LSC. As a result, the interfaces I2 and O1 have no usable switching capability, and their switching capability becomes “Nothing”.
[0046]
In this case, the switching capability monitoring unit BL5 of the control unit CNT of the node J indicates that the current switching capability of the interfaces I1 and O2 in the node 3 is “LSC”, and the current switching capability of the interfaces I2 and O1 in the node 3 is “ Nothing "is determined, and the current switching capabilities of these interfaces I1, I2, O1, and O2 are updated and stored in the link state DB · BL2.
[0047]
In other words, in the link state DB · BL2 in the node J, “LSC” has been stored as the switching capability of the interfaces I1, I2, O1, and O2 in the node J. Of these, the switching of the interfaces I2 and O1 The ability is changed from “LSC” to “Nothing”. The flooding unit BL1 of the node J displays the current switching capability of the interfaces I1, I2, O1, and O2 updated and stored in the link state DB · BL2 together with other nodes H and K together with the unique information (for example, IP address) of the interface. Advertise to.
[0048]
As a result, the link state information in the link state DB · BL2 at the nodes H, J, and K is rewritten, and the switching ability of the interface I2 and O1 of the node J is “Nothing” according to the current state in the link state information. " As a result, there is no problem that an appropriate path cannot be selected at the time of route calculation or an appropriate optical path cannot be set at the time of setting an optical path.
[0049]
[Setting example 2 of optical path in optical IP communication network]
FIG. 3 shows another setting example of the optical path in the optical IP communication network. In this example, the nodes L, M, and N are type III nodes, the source node is the node L, the destination node is the node M, the route calculation is performed in the control unit CNT of the node L, and the calculated route is the control path S1. To the node M, the optical paths # 1 and # 2 are set between the node L and the node M.
[0050]
That is, the output port P of the IP router L1 of the node L _out1 Through the interface O1 of the wavelength router L2 of the node L, the interface I1 of the wavelength router M2 of the node M, and the input port P of the IP router M1 of the node M _in1 And the output port P of the IP router L1 of the node L _out2 Through the interface O3 of the wavelength router L2 of the node L, the interface I3 of the wavelength router M2 of the node M, and the input port P of the IP router M1 of the node M _in2 Optical path # 2 leading to is set.
[0051]
Further, with the source node as M and the destination node as a downstream node not shown in the figure, the control unit CNT of the node M performs route calculation, and sends the calculated route to the node N via the control path S2, whereby the node Optical path # 3 is set between M and node N. That is, the output port P of the IP router M1 of the node M _out1 Then, the optical path # 3 that enters the interface I3 of the wavelength router N2 of the node N through the interface O3 of the wavelength router M2 of the node M and exits from the interface O3 of the wavelength router N2 is set. The nodes L, M, and N have a switching capability monitoring unit BL5 in their control unit CNT, similarly to the node 3 shown in FIG.
[0052]
In the example of FIG. 3, when the optical path # 1 is set, in the node L, the interface O1 of the wavelength router L2 is changed to the output port P of the IP router L1. _out1 And the interface I1 of the wavelength router M2 is connected to the input port P of the IP router M1. _in1 Are connected using LSC.
[0053]
In setting the optical path # 2, the interface O3 of the wavelength router L2 is connected to the output port P of the IP router L1 at the node L. _out2 Are connected to each other using the LSC, and at the node M, the interface I3 of the wavelength router M2 is connected to the input port P of the IP router M1. _in2 Are connected using LSC.
[0054]
In setting the optical path # 3, the interface O3 of the wavelength router M2 is connected to the output port P of the IP router M1 in the node M. _out1 In the node N, the interfaces I3 and O3 of the wavelength router N2 are connected using the LSC.
[0055]
Therefore, the interfaces O1 and O3 of the node L and the interfaces I1, I3, and O3 of the node M have no LSC as switching capability, and only the PSC remains. Also, the switching capability of the interfaces I3 and O3 of the node N is lost for both LSC and PSC, and becomes “Nothing”.
[0056]
In this case, the switching capability monitoring unit BL5 of the control unit CNT of the node L indicates that the current switching capability of the interfaces I1, I2, I3, and O2 in the node L is “PSC + LSC”, and the current switching capability of I4 and O4 is “PSC”. The current switching capabilities of O1 and O3 are determined to be “PSC”, and the current switching capabilities of these interfaces I1 to I4 and O1 to O4 are updated and stored in the link state DB · BL2.
[0057]
That is, in the link state DB · BL2 in the node L, “PSC + LSC” is used as the switching capability of the interfaces I1 to I3 and O1 to O3 in the node L, and the switching capability of the interfaces I4 and O4 in the node L is “ “PSC” is stored, but the switching capability of the interfaces O1 and O3 is changed from “PSC + LSC” to “PSC”. The flooding unit BL1 of the node L indicates the current switching capability of the interfaces I1 to I4 and O1 to O4 updated and stored in the link state DB · BL2 together with other nodes M and N together with unique information (for example, IP address) of the interface. Advertise to.
[0058]
In addition, the switching capability monitoring unit BL5 of the control unit CNT of the node M indicates that the current switching capability of the interfaces I2, O1, and O2 in the node M is “PSC + LSC”, and the current switching capability of I4 and O4 is “PSC”, I1 , I3, O3 is determined to be “PSC”, and the current switching capabilities of these interfaces I1-I4, O1-O4 are updated and stored in the link state DB · BL2.
[0059]
That is, in the link state DB · BL2 in the node M, “PSC + LSC” is used as the switching capability of the interfaces I1 to I3 and O1 to O3 in the node M and “switching capability of the interfaces I4 and O4 in the node M is“ “PSC” is stored, but the switching capability of the interfaces I1, I3, and O3 is changed from “PSC + LSC” to “PSC”. The flooding unit BL1 of the node M updates the current switching capability of the interfaces I1 to I4 and O1 to O4 updated and stored in the link state DB · BL2 together with the unique information (for example, IP address) of the other nodes L and N. Advertise to.
[0060]
Further, the switching capability monitoring unit BL5 of the control unit CNT of the node N indicates that the current switching capability of the interfaces I1, I2, O1, and O2 in the node N is “PSC + LSC”, and the current switching capability of I4 and O4 is “PSC”. , I3 and O3 are determined to be “Nothing”, and the current switching capabilities of these interfaces I1 to I4 and O1 to O4 are updated and stored in the link state DB · BL2.
[0061]
That is, in the link state DB · BL2 in the node N, “PSC + LSC” is used as the switching capability of the interfaces I1 to I3 and O1 to O3 in the node N until then, and the switching capability of the interfaces I4 and O4 in the node M is “ “PSC” is stored, but the switching capability of the interfaces I3 and O3 is changed from “PSC + LSC” to “Nothing”. The flooding unit BL1 of the node N displays the current switching capability of the interfaces I1 to I4 and O1 to O4 updated and stored in the link state DB · BL2 together with the specific information (for example, IP address) of the other nodes L and M. Advertise to.
[0062]
As a result, the link state information in the nodes L, M, and N is rewritten, and in the link state information, the switching capabilities of the interfaces O1 and O2 of the node L and the interfaces I1, I3, and O3 of the node M are immediately updated. “PSC”, and the switching capability of the interfaces I3 and O3 of the node N is “Nothing” in accordance with the current state. As a result, there is no problem that an appropriate path cannot be selected at the time of route calculation or an appropriate optical path cannot be set at the time of setting an optical path.
[0063]
In the above, when no switching capability is left in the interface, “Nothing” indicating this state is advertised to other nodes as the current switching capability, but the information “Nothing” is not necessarily advertised. You do not have to. For example, when advertising the switching capability of the interface in the own node, the switching capability and unique information (for example, IP address) may not be advertised only for the interface that does not have the switching capability. In any case, as described above, it is ensured that the interfaces are all “Nothing” so that RA (Routing Adjacency) cannot be established between adjacent nodes.
[0064]
In the above description, the switching ability of the interface that has not been changed is also advertised to other nodes. However, only the switching ability of the changed interface may be advertised to other nodes. That is, the switching capability of the interface that has not been changed may be left as it is, and only the switching capability of the changed interface may be updated and stored in the own node and advertised to other nodes.
[0065]
[Problem of example in FIG. 3 (1)]
In the example of FIG. 3, the output port P of the IP router L1 in the node L _out1 , P _out2 Are used by the optical paths # 1 and # 2, and the input port P of the IP router M1 in the node M _in1 , P _in2 Are used by the optical paths # 1 and # 2. For this reason, the interface O2 of the node L cannot be connected to the IP router L1, and the interface I2 of the node M cannot be connected to the IP router M1. In this case, the interface O2 of the node L and the interface I2 of the node M are “PSC + LSC”, but actually there is no switching capability of “PSC”, and only the switching capability of “LSC” remains.
[0066]
Nevertheless, in the routing protocol, the interface O2 of the node L and the interface I2 of the node M are advertised as “PSC + LSC” to other nodes in the communication network. Based on this information, when the nodes L, M, and N perform calculations for setting an optical path, in practice, an optical path is set for the node L as the source node and an optical path is set for the node M as the destination node. In spite of the fact that the optical path cannot be set, it is determined that the optical path can be set and the optical path cannot be set.
[0067]
[Problem of the example in FIG. 3 (2)]
Due to the setting of the optical path # 1, the switching capability of the interface O1 of the node L becomes “PSC”. However, when the optical path # 1 is released, it returns to “PSC + LSC”. However, since the switching capability of the interface O1 of the node L is only “PSC” while the optical path # 1 is set, the other nodes M and N do not know that they can originally be “PSC + LSC”. This is simply interpreted as an interface connected to the IP router, and traffic engineering such as route calculation is performed.
[0068]
In another example, the switching capability of the interfaces I3 and O3 of the node N becomes “Nothing” due to the setting of the optical path # 3. However, when the optical path # 3 is released, the setting returns to “PSC + LSC”. However, while the optical path # 3 is set, the switching capability of the interfaces N3 and O3 of the node N is “Nothing”, so the other nodes L and M do not know that they can originally be “PSC + LSC”. In addition, the node N is interpreted as having no interface switching capability, and traffic engineering such as route calculation is performed.
[0069]
As described above, in the example of FIG. 3, when setting the optical path with different optical path rearrangement or priority, the original switching capability information is not advertised, so that there is a problem that resources cannot be used efficiently.
[0070]
[Solution for problem (1) in the example of FIG. 3]
A solution to the problem {circle around (1)} in FIG. 3 will be described with reference to FIG. In the example of FIG. 3, it is determined that the switching capability of the interface not related to the setting of the optical path is not changed. However, at node L, output port P of IP router L1 _out1 , P _out2 Are used for the optical paths # 1 and # 2, and at the node N, the input port P of the IP router M1 _in1 , P _in2 Are used for the optical paths # 1 and # 2, the interface O2 of the node L and the interface I2 of the node M do not have the switching capability of “PSC”. Therefore, as in the example of FIG. 4, the switching capability of the interface O2 of the node L and the interface I2 of the node M is advertised as “LSC”.
[0071]
In the example of FIG. 5, the optical path # 2 is not terminated at the IP router M1 of the node M, but is relayed by the interfaces I3 and O3 of the wavelength router M2 of the node M and the interfaces I3 and O3 of the wavelength router N2 of the node N. Yes. In this case, in the node L, the output port P of the IP router L1 _out1 , P _out2 Is used for the optical paths # 1 and # 2, the interface O2 of the node L does not have the switching capability of “PSC”. The interface I2 of the node M is the input port P of the IP router M1 of the node M _in2 Is not used, it has a switching capability of “PSC”. Accordingly, in such path setting, the switching capability of the interface O2 of the node L is advertised as “LSC”, and the switching capability of the interface I2 of the node M is advertised as “PSC + LSC”.
[0072]
In the example of FIG. 6, in addition to the optical paths # 1, # 2, and # 3 shown in FIG. 4, an optical path # 4 is newly set. That is, the output port P of the IP router M1 of the node M _out2 To the interface I1 of the wavelength router N2 of the node N via the interface O1 of the wavelength router M2 of the node M, and the input port P of the IP router N1 of the node N _in2 The optical path # 4 leading to is newly set. In the case of the example of FIG. 6, as a difference from the example of FIG. 4, the switching capability of the interface O1 of the node M and the interface I1 of the node N is advertised as “PSC”, and the interface O2 of the node M is advertised as “LSC”. . Note that the interface O2 of the node M is advertised as “LSC” because the output port P of the IP router M1 of the node M is advertised. _out1 , P _out2 Is not available.
[0073]
[Solution to problem (2) in the example of FIG. 3]
A solution to the problem (2) in FIG. 3 will be described with reference to FIG. In the example of FIG. 3, for example, the switching capability monitoring unit BL5 of the control unit CNT of the node L sets the current switching capability of the interfaces I1, I2, I3, and O2 in the node L to “PSC + LSC” and the current switching of O1 and O3. The capability is determined as “PSC”, and the current switching capability of these interfaces I1 to I3 and O1 to O3 is updated and stored in the link state DB · BL2. Then, the flooding unit BL1 of the node L advertises the current switching capability of the interfaces I1 to I3 and O1 to O3 updated and stored in the link state DB · BL2 to the other nodes M and N together with the unique information of the interface.
[0074]
On the other hand, in the example of FIG. 7, the switching capability monitoring unit BL5 of the control unit CNT of the node L sets the current switching capability of the interfaces I1, I2, and I3 in the node L to “PSC + LSC (D)”, O1, O3. Is determined to be “PSC (D: Dynamic)” and the current switching capability of O2 is determined to be “LSC (D)”, and the current switching capability of these interfaces I1 to I3 and O1 to O3 (dynamic The switching state) and the inherent switching ability (static switching ability) “PSC + LSC (S: Static)” inherent to the interfaces I1 to I3 and O1 to O3 are updated and stored in the link state DB / BL2. And advertise to other nodes M and N.
[0075]
Similarly to the node L, the nodes M and N also update and store the dynamic switching capability and the static switching capability of the interface in the own node as a pair and advertise to other nodes.
As a result, the original switching capability is advertised, and resources can be used efficiently when the rearrange of the optical path and the optical paths having different priorities are set.
[0076]
In the example of FIG. 2, the same problem (2) as in the example of FIG. 3 occurs. FIG. 8 shows the solution. In the example of FIG. 8, the switching capability monitoring unit BL5 of the control unit CNT of the node J sets the current switching capability of the interfaces I1 and O2 in the node L to “LSC (D)” and the current switching capability of I2 and O1. “Nothing (D)” is determined, and the current switching capability of these interfaces I1, I2, O1, and O2 and the inherent switching capability “LSC (S)” inherent in the interfaces I1, I2, O1, and O2 Are updated and stored in the link state DB · BL2 and advertised to the other nodes M and N.
[0077]
【The invention's effect】
As is apparent from the above description, according to the present invention, the current switching capability of the interface in the own node is determined based on the usage status of the resource in the own node, and the current switching capability of this interface is determined as the own node. Since it is updated and stored and advertised to other nodes, the switching ability of the interface reflecting the resource usage status of the node is advertised, and more accurate route calculation and path setting can be performed. It becomes like this.
Further, by advertising the dynamic switching capability and the static switching capability, it becomes possible to efficiently use resources when setting rear paths of optical paths and optical paths having different priorities.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an outline of an embodiment of a node (a node provided with a switching capability monitoring unit) used in an optical IP communication network according to the present invention.
FIG. 2 is a diagram illustrating an example of setting an optical path in an optical IP communication network using a type I node and a type II node provided with a switching capability monitoring unit.
FIG. 3 is a diagram illustrating an example of setting an optical path in an optical IP communication network using a type III node provided with a switching capability monitoring unit.
4 is a diagram illustrating an example of setting an optical path in an optical IP communication network for explaining a solution to the problem (1) in the example of FIG. 3;
5 is a diagram showing an example of setting an optical path in an optical IP communication network for explaining a solution to the problem (1) in the example of FIG. 3; FIG.
6 is a diagram illustrating an example of setting an optical path in an optical IP communication network for explaining a solution to the problem (1) in the example of FIG. 3;
7 is a diagram illustrating an example of setting an optical path in an optical IP communication network for explaining a solution to the problem (2) in the example of FIG. 3;
8 is a diagram illustrating an example of setting an optical path in the optical IP communication network for explaining a solution to the problem (2) that occurs in the example of FIG. 2 in the same manner as the example of FIG. 3;
FIG. 9 is a diagram illustrating various nodes used in an optical IP communication network and switching capability classifications set in interfaces of these nodes.
FIG. 10 is a diagram illustrating an example of an optical IP communication network using type I, II, and III nodes.
FIG. 11 is a diagram showing a schematic configuration of a conventional type III node.
FIG. 12 illustrates an example of setting an optical path in an optical IP communication network using a conventional type I node and a type II node.
FIG. 13 is a diagram showing an example of setting an optical path in an optical IP communication network using a conventional type III node.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Type I node, 1-1 ... IP router, 2 ... Type II node, 2-1 ... Wavelength router, 3 ... Type III node, 3-1 ... IP router, 3-2 ... Wavelength router, I1 ~ I4, O1 ~ O4 ... interface, PSC ... switching ability to be exchanged for each packet, LSC ... switching ability to be exchanged for each wavelength, # 1 to # 4 ... optical path, H, K ... type I node , H1, K1 ... IP router, J ... type II node, J1 ... wavelength router, CNT ... control unit, BL1 ... flooding unit, BL2 ... link state DB, BL3 ... path calculation unit, BL4 ... path setting unit, BL5 ... Switching capacity monitoring unit, L, M, N ... type III node, L1, M1, N1 ... IP router, L2, M2, N2 ... wavelength router, S1, S2 ... control path.

Claims (12)

For each wavelength, a node having an interface having a switching capability to be switched for each packet, a node having an interface having a switching capability to be switched for each wavelength, an interface having a switching capability to be switched for each packet, and a wavelength In an optical IP communication network configured using at least one of nodes having an interface that can be any of the interfaces having switching capability to be exchanged,
The node determines the current switching capability of the interface in the own node based on the usage state of the resource in the own node, and updates and stores the current switching capability of the interface in the own node and advertises to other nodes. An optical IP communication network comprising a capability advertisement means. For each wavelength, a node having an interface having a switching capability to be switched for each packet, a node having an interface having a switching capability to be switched for each wavelength, an interface having a switching capability to be switched for each packet, and a wavelength In an optical IP communication network configured using at least one of nodes having an interface that can be any of the interfaces having switching capability to be exchanged,
The node determines the current switching capability of the interface in the own node based on the resource usage status in the own node, and pairs the current switching capability of the interface with the inherent switching capability of the interface. An optical IP communication network comprising switching capability advertising means for updating and storing in its own node and advertising to other nodes. In the optical IP communication network according to claim 1 or 2,
The optical IP communication network, wherein the usage status of the resource in the own node in the switching capability advertising means includes the usage status of the interface in the own node. In the optical IP communication network according to claim 1 or 2,
The optical IP communication network characterized in that the usage status of the resource in the own node in the switching capability advertising means includes the usage status of the interface in the own node and the usage status of resources other than the interface in the own node. The optical IP communication network according to claim 1, wherein when there is an interface that does not have a switching capability, the switching capability advertisement means that the switching capability is not left as the current switching capability of the interface. An optical IP communication network characterized in that information is updated and stored in its own node and advertised to other nodes. The optical IP communication network according to claim 2, wherein when there is an interface that does not have the switching capability, the switching capability advertisement means that the switching capability is not left as the current switching capability of the interface. An optical IP communication network characterized in that information and an inherent switching capability inherently possessed are updated and stored in the own node and advertised to other nodes. 3. The optical IP communication network according to claim 1, wherein the switching capability advertising means advertises the current switching capability of the interface to other nodes together with the unique information of the interface, while no switching capability is left. An optical IP communication network characterized in that, when there is an interface, the unique information of the interface is not advertised to other nodes. 3. The optical IP communication network according to claim 1, wherein at least one control path for exchanging routing protocol information is secured between adjacent nodes. . In a node with an interface having a switching capability to be exchanged for each wavelength,
Switching that determines the current switching capability of the interface in the own node based on the resource usage in the own node, updates and stores the current switching capability of the interface in the own node, and advertises to other nodes in the communication network A node comprising a capability advertisement means. In a node with an interface having a switching capability to be exchanged for each wavelength,
The current switching capability of the interface in the own node is determined based on the resource usage status in the own node, and the current switching capability of the interface and the inherent switching capability of the interface are paired and updated to the own node. A node comprising switching capability advertising means for storing and advertising to other nodes in the communication network. In a node having an interface that can be any one of an interface having a switching capability to be exchanged for each packet and an interface having a switching capability to be exchanged for each wavelength.
Switching that determines the current switching capability of the interface in the own node based on the resource usage in the own node, updates and stores the current switching capability of the interface in the own node, and advertises to other nodes in the communication network A node comprising a capability advertisement means. In a node having an interface that can be any one of an interface having a switching capability to be exchanged for each packet and an interface having a switching capability to be exchanged for each wavelength.
The current switching capability of the interface in the own node is determined based on the resource usage status in the own node, and the current switching capability of the interface and the inherent switching capability of the interface are paired and updated to the own node. A node comprising switching capability advertising means for storing and advertising to other nodes in the communication network.

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