KR100748097B1 - Route configuration method and apparatus for security of qos(quality of service) - Google Patents

Abstract

A path setup method for ensuring QoS(Quality of Service) and a device therefor are provided to more easily manage information by comprising a control processor capable of controlling connection of the overall network, and managing essential information by using a standard MIB(Management Information Base). Basic management information(MIB) essential for path setup for an MPLS(Multi Protocol Label Switching) service is collected from plural nodes within a transmission network(201). Network management information(LSR-MIB) for managing the overall network is generated by using the collected basic management information(MIB)(202). Requirements are collected from subscribers through an ingress node to generate subscriber management information(TE-MIB) according to the collected requirements(203,204). A path for ensuring QoS is searched through the generated network management information and the generated subscriber management information(205-209). It is controlled so that the ingress node can re-establish a path for the MPLS service through the searched results(210).

Description

ROUTE CONFIGURATION METHOD AND APPARATUS FOR SECURITY OF QoS (QUALITY OF SERVICE)}

1 is a block diagram showing the structure of an MPLS path setting apparatus for managing an entire transmission network according to an embodiment of the present invention;

2 is a diagram illustrating a transmission network configuration for showing MPLS rerouting according to a request of an incoming node according to an embodiment of the present invention;

3 is a flowchart illustrating an MPLS path establishment process for guaranteeing a quality of service according to an embodiment of the present invention.

The present invention relates to a path setting method and apparatus for guaranteeing a service quality, and more particularly, to a method for routing a multiprotocol label switching (MPLS) to guarantee a desired service quality by managing an entire network. And to an apparatus.

In general, MPLS is a technology standard standardized by the International Engineering Task Force (IETF), which replaces the existing Internet Protocol (IP) address-based packet transmission method with a label switching transmission method. Packet delivery in such an MPLS is performed by transmitting a packet by determining a next hop node and an output label based on a label value included in an MPLS header of an input packet.

A routing protocol is required for routing between nodes in a transmission network using the MPLS transmission scheme. To this end, the protocol used in MPLS routing typically uses RSVP-TE, a protocol for routing that guarantees quality of service such as bandwidth and delay.

However, a case in which any node among the nodes connecting the path in the incoming node does not satisfy the quality according to the request of the incoming node may occur. In this case, the entire path ensures the minimum quality according to the least quality node of all nodes. For example, if you set up a route that requires 100M bandwidth at the incoming node, but only 50M bandwidth is available at the intermediate node, even if the incoming node sends 100M bandwidth, the bandwidth of the entire path is used because it uses 50M through the intermediate node. It becomes 50M. Therefore, the conventional routing method cannot guarantee the desired quality of service.

Meanwhile, in order to manage MPLS networks, the optical management manager collects management information based on a standard MIB (Management Information Base) from a router or a switch in a conventional network management system and performs a function of showing a set MPLS path. Here, the MIB is for network management, and standards are defined in RFC3812 and RFC3813.

However, since the MIB-based network management scheme is difficult to manage the entire network, there is a problem that the subscriber cannot satisfy the desired quality of service through connection control between nodes.

Accordingly, an object of the present invention is to provide a method and apparatus for establishing an MPLS path satisfying a desired quality of service for a subscriber.

Another object of the present invention is to provide a method and apparatus for setting a path of MPLS for satisfying service quality through node-to-node connection control by applying a control processor that manages the entire network of a transport network for MPLS service.

As a path setting method for guaranteeing a quality of service for achieving the above objects of the present invention, basic management information (MIB) required for path setting for a multiprotocol level switching (MPLS) service is collected from a plurality of nodes in a transmission network. And generating network management information (LSR-MIB) for managing the entire network by using the collected basic management information (MIB), and collecting and collecting requirements from subscribers through an incoming node. Generating a subscriber management information (TE-MIB) according to requirements, searching for a path for guaranteeing a service quality through the generated network management information and subscriber management information, and the result of the search at the incoming node And controlling to reset a path for the multiprotocol level switching (MPLS) service through .

A path setting device for guaranteeing a quality of service for achieving the objects of the present invention, collecting basic management information (MIB) necessary for path setting for a multiprotocol level switching (MPLS) service from a plurality of nodes in a transmission network, A network management information management unit that generates network management information (LSR-MIB) for managing the entire network using the collected basic management information (MIB), and the requirements collected by collecting requirements from subscribers through incoming nodes A subscriber information management unit for generating a subscriber management information (TE-MIB) and a path for guaranteeing a service quality through the generated network management information and the generated subscriber management information and switching the multiprotocol level at the incoming node. (MPLS) consisting of a network control processor comprising a path manager for controlling to reset the path for the service do.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the embodiment of the present invention, a multiprotocol level switching (hereinafter referred to as MPLS) transmission scheme is applied as a method for delivering a packet through a node in a transmission network while satisfying a desired quality of service (QoS). . In the embodiment of the present invention will be described based on the Management Information Base (MIB) defined in the standard for network management according to the MPLS transmission scheme. Hereinafter, the MIB will be referred to as management information.

Next, a device for establishing an MPLS path for guaranteeing a quality of service according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a structure of an MPLS path setting apparatus for managing an entire transmission network according to an embodiment of the present invention.

Referring to FIG. 1, a transmission network is a network control device that controls a connection between a plurality of routers 11 to 15 and a plurality of routers 11 to 15 for delivering packets, and a network control processor. NCP) 100.

The network control processor 100 manages the entire transmission network, and constitutes a management information (MIB) management unit 110, a subscriber information management unit 120, and a path management unit 130.

The management information management unit 110 collects data necessary for MPLS path control from each node in the transmission network and generates network management information based on the collected data.

The subscriber information manager 120 collects service quality requirements from a subscriber, that is, from an incoming node, to generate subscriber management information, and generates the subscriber management information and the network management information generated by the management information manager 110. Maintain an association between The subscriber information management unit 120 collects the subscribed service type and service quality guarantee information from the operator of the operator's network to generate a subscriber management information table. The subscriber management information table generates the LspID of the MPLS path set according to the service. Include.

The path manager 130 finds an appropriate path through the generated management information for the MPLS path that does not satisfy the desired quality of service of the subscriber and controls the incoming node to set a new path.

The method for establishing a new packet forwarding path for guaranteeing a desired quality of service by controlling the connection of the routers 11 to 15 in the transmission network in the network control processor 100 having such a structure will be described in detail. Let's do it. First, a path setting between routers 11 to 15 in a transmission network and a path setting with an incoming node will be described, and an example of path setting for guaranteeing service quality will be described.

2 is a diagram illustrating a transmission network configuration for showing MPLS rerouting according to a request of an incoming node according to an embodiment of the present invention.

Referring to FIG. 2, for example, the incoming node 21 connects to the router 11 and establishes a path. At this time, the router 15 functions as an outgoing node, which is the last node in which the packet is transmitted to the destination. In this case, as the subscriber 100M bandwidth is required, the incoming node 21 transmits the packet to the router 11 in the 100M bandwidth for the subscriber desired quality of service. Further, for example, routers 11, 12, and 13, which are intermediate nodes, use 50M bandwidth, and router 14 and router 15, which is an outgoing node, use 100M bandwidth.

The path setting of the intermediate node and the drawing nodes may be managed through network management information generated by collecting data such as bandwidth and resources actually used from each of the nodes in the management information management unit 110. This network management information is called LSR-MIB.

In addition, the path setting in the incoming node may be managed through subscriber management information generated according to requirements from the incoming node in the subscriber information manager 120. Such subscriber management information is called TE-MIB information.

The LSR-MTB information is managed in a table form in a management information manager in association with the TE-MIB information. The LSR-MTB information table is as shown in Table 1 below. This is for the sake of simplicity, for example, and it should be noted that it may be modified according to the operator and the management processor.

mode MPLS path Bandwidth One 11 (50M) -12 (100M) -15 (100M) 50M 2 11 (50M) -13 (50M) -15 (100M) 50M 3 11 (50M) -14 (100M) -15 (100M) 50M 4 11 (50M) -13 (50M) -12 (100M) -15 (100M) 50M 5 11 (50M) -14 (100M) -12 (100M) -15 (100M) 50M 6 12 (100M) -15 (100M) 100M 7 12 (100M) -13 (50M) -15 (100M) 50M 8 12 (100M) -14 (100M) -15 (100M) 100M 9 12 (100M) -11 (50M) -13 (50M) -15 (100M) 50M 10 12 (100M) -11 (50M) -14 (100M) -15 (100M) 50M 11 13 (50M) -15 (100M) 50M 12 13 (50M) -12 (100M) -15 (100M) 50M 13 13 (50M) -12 (100M) -14 (100M) -15 (100M) 50M 14 13 (50M) -11 (50M) -12 (100M) -15 (100M) 50M 15 13 (50M) -11 (50M) -14 (100M) -15 (100M) 50M 16 14 (100M) -15 (100M) 100M 17 14 (100M) -12 (100M) -15 (100M) 100M 18 14 (100M) -11 (50M) -12 (100M) -15 (100M) 50M 19 14 (100M) -11 (50M) -13 (50M) -15 (100M) 50M 20 14 (100M) -12 (100M) -13 (50M) -15 (100M) 50M

If the subscriber wants to transmit a packet with 100M bandwidth through the incoming node 21, 100M bandwidth is included in the table of the TE-MTB as the quality of service information. Here, the table of the TE-MTB includes subscriber information collected from the operator of the operator network and the LspID of the MPLS path set according to the service.

Then, the process of resetting the MPLS path to satisfy the desired quality of service according to the requirements of the incoming node 21 will be described with reference to the accompanying drawings.

3 is a flowchart illustrating an MPLS path establishment process for guaranteeing a quality of service according to an embodiment of the present invention.

Referring to FIG. 3, in step 201, the network control processor 100 transmits data such as bandwidth, resources, etc., that is, basic management information from each router (node) 11 to 15 in the transmission network in the network information manager 110. Collect the MIB, generate the network management information (LSR-MIB) that knows the resources of the MPLS path configured in each node using the basic management information (MIB) collected in step 202, and use the generated LSR-MIB You can draw the connection status between each node. At this time, the network management information (LSR-MIB) is stored and managed in the form of a table.

Then, in step 203, the network control processor 100 checks whether there is a requirement transmitted from the subscriber, that is, from the incoming node 21. As a result of the check, if there is no requirement, the network control processor 100 returns to step 203 to maintain a standby state, and if there is a requirement, performs step 204.

In step 204, the network control processor 100 collects the requirements of the incoming node 21 from the subscriber network manager 120 and generates the subscriber management information (TE-MIB) of the path set according to the collected requirements. do. At this time, subscriber information can be collected from the incoming node 21 and network resource information actually used from the intermediate nodes 11 to 14 and the withdrawal node 15 using the generated TE-MIB. The network control processor 100 has an association relationship with the TE-MIB generated by the subscriber network manager 120 and the LSR-MIB generated by the management information manager 110. The connection between the LSR-MIB and the TE-MIB can be easily found using the LspID, which is an item of the MIB element.

Then, in step 205, the network control processor 100 through the path management unit 130, the service quality information of the network management information (LSR-MIB) generated by the network management information management unit 110 and the network management information (LSR) -MIB) compares the resource information of the path. For example, since the network control processor 100 requires the incoming node 21 to use 100M bandwidth, the network control processor 100 compares the modes of the LSR-MIB table of Table 1 with each other. Accordingly, in step 206, the network control processor 100 checks whether the comparison result satisfies the quality of service (QoS), and if it is satisfied, designates all nodes of the corresponding path in step 207, and proceeds to step 208. On the other hand, if it is not satisfied, in step 208, it is checked whether it is the comparison of the last mode. If it is not the last step, it moves to the next mode in step 212 and performs step 205 again, and in the case of the last comparison, step 209 is performed.

In step 209, the path management unit 130 of the network control processor 100 finds a path capable of guaranteeing the MPLS quality of service by viewing the result specified in step 207. For example, in Table 1, since the router 12 and the router 14 use 100M bandwidth, quality of service may be guaranteed when the routers 12 and 14 serve as intermediate nodes. Therefore, in Table 1, the quality of service can be guaranteed in the 6, 8, 16, and 17 modes. At this time, if there is no path capable of guaranteeing the quality of service, the packet for the MPLS service is transmitted through the existing path. However, it should be noted that in the embodiment of the present invention, it is assumed that there are at least one path satisfying the service quality in steps 205 to 209.

Therefore, in step 210, the path manager 130 of the network control processor 100 transmits the search result to the incoming node 21 to reset the MPLS path to the incoming node. For example, in Table 1, rerouting information for the 6, 8, 16, 17 mode path having the minimum bandwidth of 100M bandwidth is transmitted to the incoming node 21. Accordingly, the incoming node 21 receives the rerouting information and reestablishes a path for transmitting a packet for an MPLS service. After that, when the resetting is completed in the incoming node 21, the path manager 130 of the network control processor 100 transmits a control signal to delete the previously set path in step 211. Accordingly, the incoming node 21 deletes the previously set path.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention includes a control processor that can control the connection of the entire network in providing the MPLS service, and the information can be more easily managed by managing necessary information using a standard MIB in the control processor. There is an effect that can facilitate the operation of the network operator.

In addition, since the control processor resets a path that provides a sufficient quality of service (bandwidth, etc.) before the set path congestion occurs through the information collected and managed by the entire network, the service quality desired by the subscriber is guaranteed. There is an effect that can prevent in advance the congestion that can occur during service.

Claims (11)

Collecting basic management information (MIB) required for routing for multiprotocol level switching (MPLS) services from a plurality of nodes in a transport network; Generating network management information (LSR-MIB) for managing the entire network using the collected basic management information (MIB); Collecting the requirements from the subscriber through the incoming node and generating the subscriber management information (TE-MIB) according to the collected requirements; Searching for a path for guaranteeing a quality of service through the generated network management information and subscriber management information; And controlling the incoming node to reestablish a path for the multiprotocol level switching (MPLS) service through the searched result. The method of claim 1, And setting the generated network management information and the subscriber management information to have an association relationship with each other. The method according to claim 1 or 2, And when the resetting of the path for the MPLS service is completed, controlling to delete the preset path from the incoming node. The process of claim 1, wherein the searching for the path for guaranteeing the quality of service through the generated network management information and subscriber management information comprises: Comparing the subscriber management information with the network management information; Confirming whether the subscriber satisfies a desired quality of service through the comparison result; Designating all nodes of the corresponding path when the quality of service is satisfied; And searching for a path through which the quality of service can be guaranteed through the information of all the specified nodes. The method of claim 4, wherein If the service quality is not satisfied, repeating the steps until the last mode of the network management information. The method of claim 4, wherein Comparing the subscriber management information and the network management information, the service quality guarantee information included in the subscriber management information and the mode indicating the resource information of the path set for each node in the network management information, respectively, characterized in that How to establish a path to ensure quality of service. Network management for collecting the whole network management information (MIB) required for routing for multiprotocol level switching (MPLS) services from multiple nodes in the transport network and managing the entire network using the collected basic management information (MIB). A network management information management unit generating information (LSR-MIB), A subscriber information management unit that collects requirements from subscribers through an incoming node and generates subscriber management information (TE-MIB) according to the collected requirements; And a path manager configured to search for a path for guaranteeing a service quality through the generated network management information and the generated subscriber management information and to reset the path for the multiprotocol level switching (MPLS) service in the incoming node. Path setting device for ensuring the quality of service, characterized in that consisting of a network control processor. The method of claim 7, wherein And the subscriber information manager sets the generated network management information and the subscriber management information to have a correlation with each other. The method of claim 7, wherein If the path management unit compares the subscriber management information with the network management information and finds information satisfying the quality of service desired by the subscriber, designates all nodes of the corresponding path according to the found information, and determines the information through all the designated nodes. And resetting a path for the MPLS service by searching for a path capable of guaranteeing a service quality. The method of claim 9, The route management unit compares the service quality guarantee information included in the subscriber management information with the modes indicating resource information of the route set for each node in the network management information. . The method according to claim 7 or 9, And the path management unit controls to delete a preset path when the resetting of the path for the MPLS service is completed in the incoming node.

Images