JP2003046548A - Path controller and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a service with a plurality of quality classes at a low cost, even in a large scale IP network in a scalable manner. SOLUTION: An information collection section 1 collects path calculation information 2A from a network, a path calculation section 3 creates a path table 2B by each quality class on the basis of algorithm, depending on the individual quality classes from the path calculation information 2A and stores the table 2B, in advance to a storage section 2. A class identification section 5 identifies the quality class, to which a received packet belongs when transferring the received packet, and a path controller uses a path table, corresponding to the quality class of the received packet identified with a class identification section 5 among path tables stores in the storage section 2 and uses a packet transfer section 4 to transfer the received packet to an interface, corresponding to the transfer address.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a route control device and method, and more particularly to a route control device and method for controlling quality of a plurality of classes of services by controlling routes in a packet switched network service. Is.

[0002]

2. Description of the Related Art With the spread of Internet use, IP
The importance of networks is increasing. In such a situation
As data flowing through the IP network, data that does not require a quick response such as WWW browsing and emails and quality assurance, data that requires urgency such as payment information, and even prompt response such as voice and video It is necessary to appropriately perform transfer processing on data that requires different transfer qualities, such as data that requires data transfer. In such a packet-switching network as an IP network, in routing control, the routing control device of the transfer destination is determined on the basis of the routing table held by the routing control device on each routing control device (router) that passes through. As a result, it is possible to handle the flows flowing on the network as a bundle, and perform the processing corresponding to the large scale without paying attention to the individual flows.

As a result, it is easy to increase the scale by handling individual flows in a bundle instead of handling them as in a telephone, but it is difficult to control and guarantee the quality individually. As a technique for allocating a plurality of services and users to different quality classes and controlling the quality for each class, there is a method of using different routes for different classes. As one of them, as a storage route for specific services,
There is a method of manually specifying the transit router,
There is a problem in scalability when providing services in multiple classes in a large-scale IP network.

On the other hand, OSPF (Open Shortest Path Firs) for calculating a route with the residual bandwidth as a constraint condition.
There is a method of automatically calculating a route by expanding a protocol such as t / RFC1247). FIG. 4 shows a block diagram of a conventional route control device (router). In this route control device 50, the information collection unit 51 collects the route calculation information 52A from the IP network, and based on this, the route calculation unit 53 determines the interface to which the packet is to be transferred corresponding to the transfer address of the packet. , And generates a route table 52B as shown in FIG. Then, when the packet is actually transferred by the packet transfer unit 54, the packet is transferred to any one of the interfaces 61 to 63 determined by the route table 52B based on the transfer address of the packet.

[0005]

However, according to such a conventional route control device, when a service is provided in a plurality of classes in a large-scale packet switching network, the method of dynamically calculating the route has scalability. However, since there is only one routing table and an algorithm for generating the routing table, there is a problem that the packet transfer quality is limited when dealing with packets having many quality classes. The present invention is intended to solve such problems, and an object of the present invention is to provide a routing control apparatus and method that are scalable and can provide services of a plurality of quality classes at low cost even in a large-scale packet switching network. I am trying.

[0006]

In order to achieve such an object, the route control device according to the present invention is used in a packet-switched network composed of a plurality of route control devices connected in a mesh form via an interface. A routing controller that transfers the input packet to an interface corresponding to the transfer address of the input packet among the plurality of interfaces, and inputs each input packet using the algorithm according to the quality class to which the input packet belongs. The packet is transferred to the interface corresponding to the transfer address of the packet.

Further, another route control device according to the present invention is used in a packet-switched network composed of a plurality of route control devices connected in a mesh form via an interface, and a transfer address of an input packet among a plurality of interfaces. A routing control device that transfers the input packet to an interface corresponding to, and is provided for each quality class of the packet, and based on an algorithm corresponding to the quality class, the transfer address of the input packet belonging to the quality class and the packet. Storage unit that stores in advance a plurality of route tables that associate interfaces with which to transfer, a class identification unit that identifies the quality class to which the input packet belongs, and a class identification unit that is one of the route tables stored in the storage unit. To the quality class of the input packet identified by Using the route table, in which and a packet transfer unit transfers the input packet to the interface corresponding to the forwarding address.

As a configuration for generating a route table, an information collecting unit that collects route calculation information from a packet-switched network, and route calculation information collected by this information collection unit are used to correspond to individual quality classes. A route calculation unit that generates a route table for each quality class based on the algorithm may be further provided.

Further, the route control method according to the present invention is used in a packet-switching network composed of a plurality of route control devices connected in a mesh through interfaces, and corresponds to a transfer address of an input packet among a plurality of interfaces. A routing control method for transferring the input packet to an interface that uses the algorithm according to the quality class to which the input packet belongs, and transfers each input packet to the interface corresponding to the transfer address of the input packet. It is a thing.

Further, another route control method according to the present invention is used in a packet-switching network composed of a plurality of route control devices connected in a mesh form through an interface, and a transfer address of an input packet among a plurality of interfaces. A routing control method for transferring the input packet to an interface corresponding to, which is provided for each quality class of the packet, and based on an algorithm corresponding to the quality class, the transfer address of the input packet belonging to the quality class and the packet. Is stored in advance, and when the input packet is transferred, the quality class to which the input packet belongs is identified, and among the respective route tables stored in the storage unit, Routing table for the quality class of the identified input packet Using, in which so as to transfer to the interface corresponding to the input packet to the forwarding address.

Also, route calculation information is collected from the packet-switched network, and from the collected route calculation information, based on an algorithm corresponding to each quality class,
The route table is generated for each quality class.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a route control device according to an embodiment of the present invention. The route control device (router) 10 has interfaces 11 to 11 with other route control devices that form an IP network.
They are connected to each other via a mesh 13. The route control device 10 is provided with an information collection unit 1, a storage unit 2, a route calculation unit 3, a packet transfer unit 4, and a class identification unit 5. In the following, IP is used as a packet switching network.
The case of using a network will be described as an example, but the present invention is not limited to this.

The information collecting unit 1 is provided with a distance between the route control devices,
IP for route calculation information 2A such as delay time and free bandwidth
Get from the network. The collected route calculation information 2A is stored in the storage unit 2. The route calculation unit 3 uses the route calculation information 2A stored in the storage unit 2 to determine the interface for transferring the input packet, and generates the route table 2B. The generated route table 2B is stored in the storage unit 2. At this time, the route calculation unit 3 performs route calculation using an algorithm different for each quality class, and generates the route table 2B for each quality class.

The class identification section 5 identifies the quality class to which the input packet belongs. The packet transfer unit 4 includes the storage unit 2
The input packet is transferred to an appropriate interface by using the route table 2B stored in. At this time, the route table 2B corresponding to the quality class of the input packet identified by the class identification unit 5 is referred to, and the interface corresponding to the transfer address of the packet is determined. Figure 2
Shows an example of the structure of the route table. For example, when the quality classes A and B exist, the route tables 21 and 22 are individually generated and used for each class. Therefore, for example, a packet that belongs to class A and has a transfer address of Y is transferred to the interface 12, and if the class to which the transfer address belongs is Y but belongs to B, the packet is transferred to the interface 11.

FIG. 3 shows a simulation result of the route control method according to the present invention. In the simulation, DiffServ (Differentiated Servi), which is one of the class-based priority control technologies, is used as the packet transfer technology.
ces) and MPLS (Mul, which is being standardized by IETF)
tiProtocol Label Switching) was used. MPLS
Uses a short fixed-length (32-bit) identification indicator called “label” instead of an IP header when transferring an IP packet, and a label is added by an ingress edge router of an MPLS compatible network. It is transferred sequentially within the network. Then, the label is removed at the egress edge router and transferred to the external network.

Further, in DiffServ, EF class such as VoIP (Voice over IP) which is severe in delay and BE class of best effort such as data transfer are assumed as quality classes. As a method of associating this quality class with an MPLS label, that is, as a quality class accommodation method, two different accommodation methods 1 (E-LSP: EXP-In
ferred-PSC Label Switching Path) and accommodation method 2 (L
-LSP: Label-Only-Inferred-PSC Label Switching
Path) and were used. In the route control device, it is assumed that the EF class packet is preferentially transferred by the priority queue.
The network has a 3 × 5 grid pattern, and the bandwidth of the link (interface) connecting the respective route control devices is 100. The delay (metric) in each link was selected from the integer values of 1 to 10 with equal probability, and the traffic was generated with equal probability from the integer value of 1 to 5 among all the route control devices. The ratio of EF and BE was set to 1: 4.

As the routing algorithm of MPLS, WS (widest-shortest) that selects the path with the largest free bandwidth among the paths with the smallest metric delays, and the path with the smallest metric delay among the paths with the largest free bandwidth is selected. SW (shortest-widest) was used. Further, as the routing algorithm of the present invention, WS is used so that the delay is small for the EF class packet, and the BF
SW was used to smooth the link utilization for the class of packets. At the time of evaluation, since the EF class assumes a case where the delay is severe, the quality is compared with the maximum value of the LSP delay of the EF, and it is assumed that congestion is eliminated in the entire network. The quality was compared with the maximum value.

As a result of the simulation, as shown in FIG. 3, the maximum path delay of the EF class is better as expected, when the SW is adopted, and the maximum link utilization rate is improved regardless of the accommodation method. Was better in the case of adopting WS. According to the routing algorithm of the present invention, the maximum path delay of the EF class is suppressed to the same level as SW, and the maximum link usage rate is also suppressed to the same level as WS, and the respective algorithms are comprehensively evaluated. The result of taking advantage of is obtained. In this way, the packets are transferred using the route table generated by using the route calculation algorithm for each class, so that even in a large-scale IP network, scalable and multiple quality classes can be provided. While you can
As a result, the network can be used efficiently and the service can be provided at low cost.

[0019]

As described above, according to the present invention, each input packet is transferred to the interface corresponding to the transfer address of the input packet by using the algorithm according to the quality class to which the input packet belongs. In comparison with the conventional method that forwards packets based on a single algorithm, it is possible to provide multiple classes of quality in a scalable manner even in a large-scale IP network, and as a result, the network is efficiently used at low cost. Can provide services.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a route control device according to an embodiment of the present invention.

FIG. 2 is a configuration example of a route table according to the present invention.

FIG. 3 is a simulation result of the present invention.

FIG. 4 is a block diagram showing a configuration of a conventional route control device.

FIG. 5 is a configuration example of a route table according to the present invention.

[Explanation of symbols]

1 ... Information collection unit, 2 ... Storage unit, 2A ... Route calculation information,
2B ... Route table, 3 ... Route calculation unit, 4 ... Packet transfer unit, 5 ... Class identification unit.

Claims (6)

[Claims] 1. Used in a packet-switched network composed of a plurality of routing control devices connected in a mesh form via an interface, the input packet is transferred to an interface corresponding to a transfer address of the input packet among the plurality of interfaces. A routing control device comprising means for forwarding each input packet to an interface corresponding to a forwarding address of the input packet by using an algorithm according to a quality class to which the input packet belongs. 2. Used in a packet-switching network composed of a plurality of routing control devices connected in a mesh through an interface, and transferring the input packet to an interface corresponding to a transfer address of the input packet among the plurality of interfaces. A route control device, which is provided for each quality class of a packet and which associates a transfer address of an input packet belonging to the quality class with an interface to which the packet is to be transferred based on an algorithm according to the quality class A storage unit that stores a table in advance, a class identification unit that identifies the quality class to which the input packet belongs, and a quality class of the input packet that is identified by the class identification unit among the routing tables stored in the storage unit. Use the route table corresponding to And a packet transfer unit that transfers the input packet to an interface corresponding to the transfer address. 3. The route control device according to claim 2, wherein an individual information quality is calculated from an information collection unit that collects route calculation information from the packet-switched network and route calculation information collected by the information collection unit. A route control device further comprising: a route calculation unit that generates the route table for each quality class based on an algorithm according to a class. 4. Used in a packet-switching network composed of a plurality of routing control devices connected in a mesh through an interface, and transferring the input packet to an interface corresponding to a transfer address of the input packet among the plurality of interfaces. A routing control method, wherein each input packet is transferred to an interface corresponding to a transfer address of the input packet by using an algorithm according to a quality class to which the input packet belongs. 5. Used in a packet-switching network composed of a plurality of routing control devices connected in a mesh form via an interface, and transferring the input packet to an interface corresponding to a transfer address of the input packet among the plurality of interfaces. A route control method, wherein a plurality of routes are provided for each quality class of a packet and associate a transfer address of an input packet belonging to the quality class with an interface to which the packet is to be transferred, based on an algorithm corresponding to the quality class. When storing the table in advance and transferring the input packet, the quality class to which the input packet belongs is identified, and the quality class of the identified input packet among the route tables stored in the storage unit is identified. Route the input packet using the route table Routing method characterized by transferring to the interface corresponding to the forwarding address. 6. The route control method according to claim 5, wherein route calculation information is collected from the packet-switched network, and based on the collected route calculation information, based on an algorithm corresponding to each quality class, A routing control method characterized in that the routing table is generated for each quality class.