KR100441889B1 - MPLS network management system and method thereof - Google Patents

Abstract

The present invention relates to a multiprotocol label switching (MPLS) network management apparatus and a management method. Specifically, a graphical user interface method and a method for representing a multiprotocol label switching (MPLS) topology view The present invention relates to a computer-readable recording medium having recorded thereon a program for realizing this.

By visualizing various management information of a multi-protocol label switching (MPLS) network at a glance by the method and apparatus proposed by the present invention, an administrator can conveniently and accurately perform complicated management tasks, and maintenance and training costs required for network management. Can be significantly reduced.

Description

Multiprotocol Label Switching Network Management System and Management Method

The present invention relates to a multiprotocol label switching (MPLS) network management apparatus and a management method, and to a graphical user interface method for representing a multiprotocol label switching (MPLS) topology view and realizing the method. The present invention relates to a computer-readable recording medium having recorded thereon a program.

Specifically, the configuration of a multi-protocol label switching (MPLS) network management system will be described and its management method will be described. In addition, multi-protocol label switching (MPLS) topologies are classified into four types, and the traffic state of the multi-protocol label switching (MPLS) network managed by the network manager, various resource states set in the network, and label switching set in the network. Multiprotocol label that visualizes the relationship between the path (LSP) and the topology of the physical link at a glance, avoiding relatively difficult management methods that depended on the experience and manual methods of traditional administrators, and enable convenient and accurate management A method for presenting a multi-protocol label switching (MPLS) topology view of a user interface of a switching (MPLS) traffic engineering management system and a computer-readable recording medium recording a program for realizing the method. .

In the conventional IP packet exchange method, a router that receives data repeats a process of retrieving a large number of IPs and transmitting data through a route calculation process for determining the next router, which is hop-by-hop. It is called a hop-by-hop method and is classified as a connectionless IP switching system in that it is stopped and transmitted for each router.

However, due to the rapid increase of Internet users, the number of IP (IP) addresses managed by one router and the amount of data waiting to be processed by the route calculation process are so high that the congestion of the Internet traffic can not be handled efficiently. It began to occur, and as telecom operators expanded their facilities, such as routers, to solve this problem, the profitability decreased. In addition, communication speeds depended on the speed of the entire network, allowing for the development of differentiated new products in terms of speed, continuity, and price. Consumers' dissatisfaction with using the same speed and price regardless of personal needs was high.

To solve this problem, multi-protocol label switching (MPLS) is a next-generation packet transmission method created by the Internet Engineering Task Force (IETF). This is a connection type IP (IP) exchange system that transmits a packet by switching only by attaching a label in which a predetermined path is recorded on the packet, without performing a route calculation process.

By eliminating the route calculation process and reducing the burden of IP management on the router, speed can be increased and a quality of service (QoS) can be created by speed, continuity, and price.

1 is a diagram illustrating the structure of a multi-protocol label switching (MPLS) network.

As shown in FIG. 1, the IP packet is labeled at the inlet router 101, and then, in all intermediate routers, label switching is performed by this label rather than the IP packet header. Has a structure in which packets are delivered.

The path through which the labeled IP packet passes is called a Label Switched Path (LSP), which is typically required to be established by various routing protocols. It is actually established by a newly standardized signaling protocol such as Label Distribution Protocol (LDP) or RSVP. To this end, the label switch router (LSR) 102, which is an intermediate router having a multi-protocol label switching (MPLS) function, has a routing protocol as well as a forwarding function and a signaling protocol using label switching.

Thus, since this architecture has a routing protocol in every Label Switch Router (LSR) 102, the routing protocol of an Edge Router is a routing protocol that is located in a Label Switch Router (LSR) 102 to which it is physically directly connected. You only need to establish a routing peer with the protocol.

The multi-protocol label switching (MPLS) traffic engineering technology proposed by the present invention is a new technology in the early stages of introduction at home and abroad, and there is no systematic and comprehensive integrated management tool. In the conventional method, multi-protocol label switching (MPLS) traffic engineering technology is proposed. Most of them rely on passive and empirical methods for traffic engineering management.

In particular, this technology is applied to the backbone network of large Internet service providers that provide Internet services. Since the number of network equipments to be managed has a complicated structure ranging from tens to thousands, it is passive or similar to the conventional method. Empirical management involves various problems that cannot meet the quality of service and the requirements of service users.

Also, in addition to passive empirical management methods, conventional management tools introduced to this market are mainly used for capacity planning, and thus traffic is based on network information at a specific moment rather than continuously reflecting the actual situation of the network. The problem was that it provided the ability to do engineering. Traffic engineering is not easy to efficiently use the network resources only limited to any particular moment, it is possible to maximize the effect by continuously providing continuous iteration and real-time information by the method proposed in the present invention.

In order to solve the above problems, the present invention proposes a multi-protocol label switching (MPLS) network management apparatus and management method, and variously visualizes topology information of the multi-protocol label switching (MPLS) network in four forms. To provide administrators with the equipment and methodology so that they can see traffic engineering information of multiprotocol label switching (MPLS) at a glance, and can conveniently and accurately manage multiprotocol label switching (MPLS) networks. The purpose.

In addition, an object of the present invention is to provide a function for continuously monitoring and visualize the actual network status information, and to provide a computer-readable recording medium recording the function providing method and a program for realizing the function.

1 illustrates the structure of a Multiprotocol Label Switching (MPLS) network.

2 is a block diagram of a multi-protocol label switching (MPLS) network management system applied to an embodiment of the present invention.

3 is a configuration diagram of a policy server PS.

4 is a configuration diagram of a proxy agent (PA).

5 is a configuration diagram of a resource monitoring server (RMS).

6 is a configuration diagram of a traffic measurement and analysis server (TMS).

7 is a diagram of a main graphical user interface (GUI) and various topologies and traffic state information windows.

8 is a menu configuration diagram of a multi-protocol label switching (MPLS) traffic engineering management system of the present invention.

9 is a logon screen of a multi-protocol label switching (MPLS) traffic engineering management system of the present invention.

FIG. 10 is a configuration diagram of a File menu among menus of the menu window. FIG.

FIG. 11 is a diagram illustrating a setup menu among menus of the menu window; FIG.

12 is a diagram illustrating a view menu among menus of the menu window.

FIG. 13 is a diagram illustrating a provisioning menu among menus of the menu window; FIG.

FIG. 14 is a diagram illustrating a monitoring menu in a menu of the menu window; FIG.

FIG. 15 is a diagram illustrating a simulation menu among menus of the menu window; FIG.

FIG. 16 is a configuration diagram of a Tools menu among menus of the menu window; FIG.

Fig. 17 is a configuration diagram of a Help menu.

18 is a diagram illustrating a multi-protocol label switching (MPLS), network components (NEs), and virtual private network (VPN) menu configurations.

FIG. 19 illustrates a hierarchical tree structure shown in a multi-protocol label switching (MPLS) tab. FIG.

20 is a diagram showing a network component (NEs) in a tree structure.

FIG. 21 is a diagram showing configuration information of a virtual private network (VPN) object in a tree structure. FIG.

FIG. 22 is a diagram of an apparatus for representing multiprotocol label switching network management information of the present invention via a graphical user interface. FIG.

FIG. 23 is a flow diagram of a method for presenting multi-protocol label switching (MPLS) network management information of the present invention via a graphical user interface (CUI). FIG.

Figure 24 is a schematic diagram of one embodiment of a complete user interface for multi-protocol label switching (MPLS) traffic engineering management of the present invention.

FIG. 25 is a diagram illustrating an embodiment of a user interface for visualizing label switching path (LSP) traffic statistics according to the present invention. FIG.

FIG. 26 is a complete detailed view of the currently set label switching path (LSP). FIG.

FIG. 27 is a diagram illustrating an embodiment of a user interface for multi-protocol label switching (MPLS) network resource reservation status visualization of the present invention. FIG.

FIG. 28 is a diagram illustrating an embodiment of a user interface for visualizing multiprotocol label switching (MPLS) network affinity information of the present invention. FIG.

FIG. 29 is a diagram illustrating an embodiment of a user interface for visualizing a multiprotocol label switching (MPLS) network physical link topology and a label switching path (LSP) tunnel relationship.

In order to achieve the above object, the present invention provides a resource monitoring server for collecting and storing network resource state information including interface statistics, topology information, and label switching path information; A traffic measurement and analysis server for measuring, collecting, analyzing, and storing traffic data including network performance and an adjacent AS traffic matrix; A proxy agent that collects router information that is not defined in the standard of the simple network management protocol and transmits it to the resource monitoring server and the traffic measurement and analysis server; A common service interface unit receiving the traffic data and network resource state information from the resource monitoring server and the traffic measurement and analysis server and transmitting the received network data to a graphical user interface unit; And a graphic user interface for visually expressing network resource state information from the resource monitoring server, traffic information analysis information from the traffic measurement and analysis server, and information from the common service interface unit, and providing the administrator with a visual representation. Provides a label switching network management device.

In order to achieve the above object, the present invention provides a resource monitoring server comprising: collecting, by a resource monitoring server, network resource status information including interface statistics, topology information, and label switching path information and storing the information in a database for a resource monitoring server; Measuring, collecting and analyzing traffic data including network performance and an adjacent AS traffic matrix by the traffic measurement and analysis server and storing the traffic data in a database for the traffic measurement and analysis server; Collecting, by the proxy agent, router related information that is not defined in the standard of the simple network management protocol and transmitting it to the resource monitoring server and the traffic measurement and analysis server; Receiving, by the common service interface unit, traffic data and network resource state information from the resource monitoring server and the traffic measurement and analysis server, and transmitting the received network data to the graphical user interface unit; And a graphic user interface unit receiving the traffic data of the network and network resource state information from the common service interface unit and visually expressing the network data to the administrator.

In order to achieve the above object, the present invention provides a computer-readable recording medium that records a program for executing the method on a computer.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a multi-protocol label switching (MPLS) network management system applied to an embodiment of the present invention.

Communication between system modules is performed using a CORBA interface, and each module is implemented using a C ++ language, a C language, or JAVA. Telnet through Common Open Policy Service (COPS) protocol, Simple Network Management Protocol (SNMP) and Proxy Agent for control and monitoring between network equipment and development system Based command line interface (CLI) technology is implemented, and overall data management is based on relational database (RDB) based on open database connectivity (ODBC) technology, and lightweight directory access. Protocol (LDAP, Lightweight Directory Access Protocol) technology was used together. The development of the system was done on Sun Solaris OS systems and can be done on Sun, Linux, and FreeBSD.

The multi-protocol label switching (MPLS) network management system includes a common service interface (CSI) 201, a graphical user interface (GUI) 202, and a policy server (PS) 203. Resource Monitoring Server (RMS) (204), Traffic Measurement Analysis Server (TMS) (205), Routing Advisor for Traffic Engineering (RATE) (206) And a proxy agent (PA) 207.

Common Service Interface (CSI) is a service interface between all the different servers. It configures Global Configuration, Multi-Protocol Label Switching-Traffic Engineering (MPLS-TE), and Virtual Private Network (VPN). It also features topology management, traffic measurement, and analysis. It is defined as a CORBA IDL interface, providing high scalability, especially connectivity and compatibility with other existing network management systems.

3 is a configuration diagram of the policy server PS.

The Policy Server (PS) is designed and implemented in accordance with the structure defined by the Internet Engineering Task Force's (IETF) Policy Framework Working Group, which is a multi-protocol label switching (MPLS) traffic engineering (TE) network-wide network. It is responsible for determining the VPN and VPN policy, and creating, modifying, deleting, and checking policy rules, policy rule enforcement, and admission control.

Devices that support the Common Open Policy Service (COPS) protocol function are directly controlled by using the Common Open Policy Service (COPS), and the Common Open Policy Service (COPS) is not supported on the device. In this case, a network agent is controlled by using a proxy agent through a common open policy service (COPS).

The functions of these Policy Servers (PS) are responsible for automatically applying complex multiprotocol label switching-traffic engineering (MPLS-TE) and virtual private network (VPN) configurations across the network. This feature can be an essential element for operators who have manually managed complex configuration information by router and can contribute to maximum efficiency in terms of time and cost of management. Particularly, a virtual private network (VPN) configuration management product has been developed in part, but multi-protocol label switching-traffic engineering (MPLS-TE) and virtual private network (VPN) configuration management based thereon are no globally important features. It can be said.

4 is a configuration diagram of the proxy agent PA.

The Proxy Agent (PA) module can accommodate routers that do not support the Common Open Policy Service (COPS) protocol from the same point of view, and provides scalability of the system by easily supporting various routers by simply adding functions. This scalability is essential for most operators who need to accommodate a variety of heterogeneous routers, and having the ability to accommodate new routers with minimal system changes, especially in the short term, will give an edge over the competition among Internet operators. It is directly related to the ability to

Network resource status monitoring and performance measurement, traffic data collection and analysis will be in charge of the resource monitoring server (RMS) and traffic measurement and analysis server (TMS) server.

5 is a configuration diagram of a resource monitoring server (RMS).

The resource monitoring server (RMS) mainly collects network resource status information such as interface statistics, topology information, and label switching path (LSP) configuration information. The traffic measurement and analysis server (TMS) includes network performance and neighboring AS traffic matrix, It is responsible for measuring, collecting, and analyzing traffic data, such as the Prefix Traffic Matrix (Adjacent AS Traffic Matrix).

The data collected from these functions is built into a database for other servers or future analysis functions, and provided to other module functions through the CORBA interface of the Common Service Interface (CSI). The resource monitoring server (RMS) has a simple network management protocol (SNMP) polling engine and proxy agent control for this function.

6 is a configuration diagram of a traffic measurement and analysis server (TMS).

The traffic measurement and analysis server (TMS) collects label switching path statistics (LSP Statistics) and router statistics through the proxy agent 207 using its own implementation of the Routing Statistics Polling Engine. It also has the ability to collect and analyze Netflow Export information from Cisco routers or Juniper routers to build traffic data. These data are used directly for traffic engineering (TE) and are provided as analytical data for future capacity planning of the network.

The resource monitoring server (RMS) or traffic measurement and analysis server (TMS) uses a proxy agent to collect various router information that is not defined in standards such as Simple Network Management Protocol (SNMP). Agent control is performed through the CORBA interface.

The routing supervisory server (RATE) for traffic engineering is responsible for supporting decision making in the policy server (203) by measuring network conditions, analyzing data, and performing various simulation functions based thereon. First of all, there is a function to verify the availability in advance when setting the label switching path (LSP), and if it is not available, cause analysis is possible even without direct command to the network, and the result is predicted when the label switching path (LSP) is modified. It provides the capability to validate various decisions for traffic engineering (TE) before directing the network.

In addition, node or link failure scenario simulation or global optimization is provided as a highly efficient function for mid- and long-term network management and operation. The Routing Supervisory Server (RATE) function for traffic engineering is monitored in real time. It is performed based on the measured data, so the reliability and accuracy are very high. The Routing Supervisory Server (RATE) for traffic engineering implements and implements the receiver functions of Open Shortest Path First (OSPF) and Border Gateway Protocol (BGP) for data collection. Based on this, the real-time network routing and resource situation is always understood.

7 is a diagram of the main graphical user interface (GUI) and various topologies and traffic state information windows.

Graphic User Interface (GUI) is implemented as a structure that can control the system on any platform where Java Virtual Machine is installed by using Java (JAVA) technology. , Analysis, label switching path (LSP) and traffic trunk (TT) definition capabilities and the ability to view the network from various views.

8 is a menu configuration diagram of a multi-protocol label switching (MPLS) traffic engineering management system of the present invention.

First, there is a Log On menu, and when the user is normally logged on, the initial screen is composed of a menu window 810, a tree window 820, a map window 830, and a legend window 840. It consists of File, Setup, View, Provisioning, Monitoring, Simulations, Tools, Windows, and Help.

The tree window 820 is composed of multi-protocol label switching (MPLS), network elements (NEs, Network Elements), and virtual private network (VPN) menus.

The map window 830 is composed of an IP topology, a multiprotocol label switching topology (MPLS Topology), a routing topology, and a virtual private network topology (VPN Topology).

9 is a logon screen of a multi-protocol label switching (MPLS) traffic engineering management system of the present invention.

If the ID and password are entered in the logon screen, the administrator ID and password are compared with the stored database, and if they are correct, the system management screen is displayed to the administrator.

FIG. 10 is a diagram illustrating the configuration of a File menu among menus of the menu window.

The watch dog manages the execution status of all running processes and checks the output. Quit performs the function of terminating a program.

FIG. 11 is a diagram illustrating a setup menu among menus of the menu window. FIG.

Setup is a function to set up or change information about router, user, data store, and agent configuration. Node Configuration 1110, User Account 1120, Database / LDAP Configuration (DB / LDAP Configuration) 1130 and Proxy Agent Setup (Proxy Agent Setup) 1140.

The node configuration 1110 performs a function of providing a window for controlling a multi-protocol label switching (MPLS) related function of a node (router) constituting the network. The user account 1120 registers a program user and performs a function for controlling authority.

The database / LDAP configuration 1130 designates a database server or an LDAP directory server for storing program configuration information and network configuration information, and performs a function for setting related information.

The proxy agent setup 1140 performs a function of setting information about a proxy agent, which is one of the components of a multi-protocol label switching (MPLS) traffic engineering management system.

12 is a diagram illustrating a view menu among menus of the menu window.

View performs the function of selecting the type of map that appears in the map window. IP Topology 1210 provides a three-layer map of routers that make up the management network. Therefore, the user can retrieve information per router or interface related to the third layer.

Routing Topology 1220 provides a map for each routing protocol operating in a router. Therefore, the user can search the routing information for each node or interface through this map.

The Multiprotocol Label Switching Topology (MPLS Topology) 1230 includes a Label Switching Path (LSP) Tunnel Stat View, a B / W Reservation View, an Affinity View, and a Link / It consists of a tunnel view (Link / Tunnel View).

When the LSP Tunnel Stat View is selected, statistical information is displayed for each LLS Tunnel configured on a multi-protocol Label Switching (MPLS) node. When B / W Reservation View is selected, allocated and reserved resource information for the link between nodes is displayed. If affinity view is selected, affinity information for each node, link, and interface is displayed. In the case of selecting a link / tunnel view, the label switching path tunnel (LSP Tunnel) information set on the two-layer topology map is displayed.

The virtual private network topology (VPN Topology) 1240 provides a function of selecting a map representing a virtual private network (VPN) configuration.

FIG. 13 is a diagram illustrating a provisioning menu among menus of the menu window. FIG.

Provisioning is a management function that creates, edits, and deletes traffic trunks (TTs), label switching path tunnels (LSP Tunnels), globals (resources classes), and other information.

Create 1310 performs a function for creating a traffic trunk (TT), a label switching path tunnel (LSPTunnel), a global (resource level), and other information. When each menu is selected, a corresponding edit window is displayed on the screen. Is displayed.

Edit 1320 performs a function for changing traffic trunk (TT), label switching path tunnel (LSP Tunnel), global (resource level), other information, and the like.

14 is a diagram illustrating a monitoring menu in the menu of the menu window.

Monitoring performs a function of displaying network traffic information collected and analyzed by a resource monitoring server (RMS) or a traffic measurement and analysis server (TMS) at various times.

Auto discovery 1410 performs a function of finding a node constituting a management network through simple network management protocol (SNMP) polling based on a seed address input by a user. Configure Polling 1420 performs a function of setting a polling period, and Interface Statistics 1430 performs a function of displaying statistical information of access traffic for each interface.

The label switching path statistics (LSP Statistics) 1440 displays statistical information of traffic for each label switching path (LSP). The adjacent autonomous system matrix 1450 performs a function of displaying traffic flow information between neighboring autonomous systems (AS). The prefix matrix 1460 performs a function of displaying traffic inflow / exit information for each prefix. The traffic trunk details display (Show TT Details) 1470 performs a function of displaying traffic statistics for each traffic trunk through a graphic.

Finally, the Show Label Details 1480 displays the traffic statistics information for each label switching path tunnel (LSP Tunnel) graphically.

FIG. 15 is a diagram illustrating a simulation menu among menus of the menu window. FIG.

Simulation provides a menu of choices for the four simulation functions performed by the RATE server for traffic engineering.

The path calculation 1510 provides a function for determining an expected path based on the current network resource state before actually setting the label switching path (LSP). Attribute Change 1520 provides a function for simulating changes in the Label Switching Path Tunnel (LSP Tunnel) that can occur when changing the attributes of a particular node or interface.

Node / Link Failure (1530) provides the ability to simulate network state changes, including label switching paths (LSPs), in the event of a node or link failure. Finally, Global Optimization (1540) is designed to simulate an optimized network configuration by batching the entire label switching path (LSP) list into the network instead of targeting individual label switching paths (LSPs). To provide.

FIG. 16 is a diagram illustrating a Tools menu of menus in the menu window.

User information is managed and the edited user information is stored in the directory server and can be edited by the administrator.

17 is a configuration diagram of a Help menu. It provides a function to easily search Help such as Table of Contents (TOC) and Index, and displays general information about the system.

FIG. 18 is a diagram illustrating a multi-protocol label switching (MPLS), network elements (NEs), and virtual private network (VPN) menus as selection menus in the tree window 820 of FIG. 8.

Create Trunk (1810) is a shortcut menu that appears when you right-click a traffic trunk item on the Multiprotocol Label Switching (MPLS) tab and displays the wizard window for creating a new traffic trunk. To perform.

Create Tunnel 1811 is a shortcut menu that appears when you select the Label Switching Path Tunnel (LSP Tunel) item and click the right mouse button to display a wizard window for creating a new Label Switching Path (LSP) tunnel. Perform the function.

The Install 1814 command sends the contents of the generated traffic trunk or Label Switching Path (LSP) tunnel objects to the router to create the actual Label Switching Path (LSP) on the destination router. The Modify 1815 command performs a function for changing an attribute of a label switching path (LSP) created in a target router. The Withdraw 1816 command performs the function to remove the label switching path (LSP) at the target router.

Statistics 1817 perform a function of displaying traffic state information of a traffic trunk or a label switching path (LSP) tunnel in a graph form.

Properties 1820 is a shortcut menu displayed by selecting a specific router (e.g. Cisco 7204) or interface (e.g. FastEthernet0 / 0) item and clicking the right mouse button. Performs the function of displaying.

Enable MPLS (1821), Enable LDP (1822), and Enable RSVP (1823) for resource reservation protocols are displayed when the right mouse button is clicked after selecting a specific interface item. It serves as a shortcut menu to activate multi-protocol label switching (MPLS), label distribution protocol (LDP) and resource saving protocol (RSVP) functions.

Disabling Multiprotocol Label Switching (Disable MPLS) 1824, Disabling Label Distribution Protocol (Disable LDP) 1825, and Disabling Resource Reservation Protocol (Disable RSVP) 1826 are displayed by right-clicking a particular interface item. It is a shortcut menu that performs a function of disabling the Multi-Protocol Label Switching (MPLS), Label Distribution Protocol (LDP), and Resource Vulnerability Protocol (RSVP) functions.

Create VPN 1830 is a shortcut menu that is displayed when a right mouse button is selected after selecting a Virtual Private Network User Admin Domain item or a Virtual Private Network Provider Admin Domain item. As a function, the wizard window for creating a new virtual private network (VPN) object is displayed.

The Install (Enforce) 1833 command performs the function of creating a real virtual private network (VPN) on the target router by sending the contents of the created virtual private network (VPN) object to the router, and the Modify (1834) command Performs a function to change the properties of the virtual private network (VPN) created in the target router. The Withdraw 1835 command performs a function for removing a virtual private network (VPN) from the target router. The statistical 1836 command displays traffic state information for each virtual private network (VPN) in the form of a graph.

The Multiprotocol Label Switching (MPLS) tab displays the traffic trunk (TT) and Label Switching Path Tunnel (LSP Tunnel) configuration information in a hierarchical tree structure.

19 illustrates a hierarchical tree structure shown in a multi-protocol label switching (MPLS) tab.

20 is a window displaying network elements NEs in a tree structure.

This window displays all routers and router-specific interface information in the management network.

21 is a diagram showing configuration information of a virtual private network (VPN) object in a tree structure.

In this figure, it is possible to identify what is reflected in the network and not reflected through the icon shape.

FIG. 22 is a diagram of an apparatus for representing multiprotocol label switching network management information of the present invention through a graphical user interface.

The resource monitoring server (RMS) 2210 collects network resource state information such as interface statistics, topology information, and label switching path information.

The resource monitoring server (RMS) 2210 collects network resource status information such as interface statistics, topology information, and label switching path (LSP) configuration information mainly, and the traffic measurement and analysis server (TMS) provides network performance and neighboring AS. It is responsible for measuring, collecting, and analyzing traffic data such as the Traffic AS Traffic Matrix and the Prefix Traffic Matrix.

The data collected from these functions is built into the database for other servers or future analysis functions and provided to other module functions through the CORBA interface of the Common Service Interface Unit (CSI). The resource monitoring server (RMS) has a simple network management protocol (SNMP) polling engine and proxy agent control for this function.

A resource monitoring server database (RMS DB) 2220 stores information collected by the resource monitoring server (RMS) 2210.

Traffic measurement and analysis server (TMS) 2230 measures, collects and analyzes traffic data, such as network performance and adjacent autonomous system traffic matrices.

The traffic measurement and analysis server (TMS) 2230 collects label switching path statistics (LSP Statistics) and router statistics through the proxy agent (2250) using its own implemented Routing Statistics Polling Engine. This is accomplished by collecting and analyzing Netflow Export information from Cisco routers or Juniper routers to build traffic data. These data are used directly for traffic engineering (TE) and are provided as analytical data for future capacity planning of the network.

A database for traffic measurement and analysis server (TMS TB) 2240 stores the information of the traffic measurement and analysis server (TMS) 2230.

The proxy agent 2250 collects router information, which is not defined in the Simple Network Management Protocol (SNMP) standard, through the command line interface (CLI) to collect the resource monitoring server (RMS) and the traffic measurement and analysis server ( TMS).

The Proxy Agent (PA) 2250 module can accommodate routers that do not support the Common Open Policy Service (COPS) protocol from the same point of view, and provides scalability of the system by easily supporting various routers simply by adding simple functions. do. This scalability is indispensable for most operators who need to accommodate a variety of heterogeneous routers, and having the ability to accommodate new routers with minimal system changes, especially in the short term, will give an edge over the competition among Internet operators. It is directly related to the ability to do so.

The common service interface unit (CSI) 2260 receives traffic data and network resource status information from the resource monitoring server (RMS) 2210 and the traffic measurement and analysis server (TMS) 2230, and receives a graphical user interface unit ( GUI (2270), configure the network management system, manage multi-protocol label switching traffic engineering (MPLS-TE) information, configure the virtual private network (VPN), and manage the topology of the network. do.

Common Service Interface (CSI) 2260 is a service interface between all other servers, which includes Global Configuration, Multi-Protocol Label Switching-Traffic Engineering (MPLS-TE) and Virtual Private Network (VPN) configuration, Topology management, traffic measurement, and analysis capabilities are defined by the CORBA IDL interface, which provides high scalability, especially connectivity and compatibility with other existing network management systems.

Graphical user interface (GUI) 2270 may include network resource status information from the resource monitoring server (RMS) 2210, traffic information analysis information from the traffic measurement and analysis server (TMS) 2230, and the common service interface. The information from the CSI 2260 is visually represented.

23 is a flowchart of a method for presenting multi-protocol label switching (MPLS) network management information of the present invention via a graphical user interface (CUI).

First, the resource monitoring server (RMS) collects network resource state information such as interface statistics, topology information, and label switching path (LSP) information and stores the information in a resource monitoring server database (RMS DB) (2310).

The traffic measurement and analysis server (TMS) measures, collects and analyzes traffic data such as network performance and adjacent autonomous system traffic matrices, and stores the data in a traffic measurement and analysis server database (TMS DB) (2320).

Network related information also exists that is not defined in the Simple Network Management Protocol (SNMP). Accordingly, the proxy agent (PA) collects router-related information not defined in the standard of the Simple Network Management Protocol (SNMP) through the command line interface (CLI), so that the resource monitoring server (RMS) and the traffic measurement and analysis server ( TMS) (2330).

Next, the common service interface unit (CSI) receives the traffic data and network resource state information from the resource monitoring server (RMS) and the traffic measurement and analysis server (TMS), and transmits it to the graphical user interface unit (GUI), Set the environment of the network management system, manage multi-protocol label switching traffic engineering (MPLS-TE) information, set the environment of the virtual private network (VPN), and manage the topology of the network (2340).

In order to display the network information in the form of a window, a menu is input from the user (2350).

In response to the selection command received in this way, the graphical user interface (GUI) receives the traffic data and network resource state information of the network from the common service interface (CSI) and visually expresses it (2360).

First, a menu for operating the management system in the operator's operating environment is displayed in the first area of the window. The menus are File, Setup, View, Provisioning, Monitoring, Simulations, Tools, Windows, Help. It is configured and described in detail below with reference to FIG.

In addition, the second window shows the label switching path (LSP) information found by the generation, modification, deletion, and auto-discovery functions of the multi-protocol label switching (MPLS) for traffic engineering in a tree form.

Next, the topology of the management network is displayed in a third area of the window according to a command received from a user in the view menu of the management system operation menu. In this case, when the label switching path traffic statistics view is selected, the current traffic state is shown for each label switching path tunnel, and when the resource reservation view is selected, the state of the reserved network resource is represented.

When the preference view is selected by the user, preference information for each node, link, and interface is displayed in the third area of the window. When the link and tunnel view is selected by the user, the physical link topology and the multi-protocol label of the management network are displayed. The label switching path tunnel information set on the switching network topology map is shown in the third region in the window.

Figure 24 is a schematic diagram of one embodiment of a complete user interface for multi-protocol label switching (MPLS) traffic engineering management of the present invention.

As shown in FIG. 24, the full user interface for multi-protocol label switching (MPLS) traffic engineering management creates, modifies, and deletes the full menu 2410, toolbar 2420, multi-protocol label switching (MPLS) for traffic engineering. And a tree control panel 2430 capable of expressing the label switching path (LSP) information found by the automatic search function, a map window 2440 capable of visualizing the topology of the management network in various forms, and traffic. It includes a color code panel 2450 and a status window 2460 for displaying the amount of use. Among the map window 2440 that can visualize the topology of the management network in various forms, the multiprotocol label switching (MPLS) topology is presented in the present invention.

All menus can be accessed from File, Setup, View, Provisioning, Monitoring, Simulations, Tools, Windows, Help. It is composed.

File manages the execution status of all running processes, examines the output, and terminates the program.

Setup performs a function for setting or changing information about router, user, data storage, and agent configuration.

View provides the ability to select the type of map that appears in the map window. IP topology, routing topology, multiprotocol label switching topology, virtual private network topology Performs the function of showing the configuration diagram for (VPN topology, Virtual Private Network topology).

Provisioning serves to create, edit, and delete traffic trunks (TTs), label switching path tunnels (LSP tunnels), global information, and other information.

Monitoring performs a function of displaying room traffic information collected and analyzed by a resource monitoring server (RMS) and a traffic measurement analysis server (TMS) at various times.

Simulation performs the function of selecting four simulation functions performed by the Routing Advisor for Traffic Engineering (RATE).

Tools provide a function to manage user information. The edited user information is stored in a directory server and can be edited by an administrator.

Help performs the help search function by table of contents and index.

25 is a diagram illustrating an embodiment of a user interface for visualizing label switching path (LSP) traffic statistics according to the present invention.

As shown in FIG. 25, the user interface for visualizing Label Switching Path (LSP) traffic statistics includes a management node, the domain name and loopback IP address 2510 of the node, a point and IP for the interface on the management node. (IP) address 2520, a link that connects the interface between the management nodes (2530), a number indicating the color code and traffic volume on the bisected link to represent the average amount of traffic for the last five minutes charged to each link. (2540).

The management node represents the actual routers in the management network and is displayed in a unique color according to the manufacturer of the router. The links are bisected and displayed in a color coded according to the amount of traffic charged, which can be scoped directly by the administrator and originated from the node to which the interface is attached, based on the attached interface points of the bisected links. Indicates the direction of traffic.

This user interface allows the administrator to see at a glance how much traffic is currently flowing in the management network and in particular which path has the highest congestion rate. In addition, if the administrator wants to check the actual detailed label switching path (LSP) detailed information that passes through the link in addition to the average amount of traffic for the last five minutes, the table as shown in FIG. 26 appears when the link is selected and double-clicked.

FIG. 26 is an overall detailed information diagram of the currently set label switching path LSP. FIG.

This table lists all label switching paths (LSPs) currently passing through this link, including start and end nodes for each label switching path (LSP), traffic volume for the last five minutes, and operational status of the label switching paths (LSPs). Detailed information is displayed.

FIG. 27 is a diagram illustrating an embodiment of a user interface for multi-protocol label switching (MPLS) network resource reservation status visualization according to the present invention.

As shown in FIG. 27, the user interface for visualizing management multi-protocol label switching (MPLS) network resource reservation status includes a management node, the domain name and loopback IP address 2710 of the node, and an interface on the management node. A number indicating the reserved bandwidth and the IP address 2720, the link 2730 connecting the interface between the management nodes, the color coded on the bisected link to represent the amount of bandwidth reserved for each link 2740.

The management node represents the actual routers in the management network and is displayed in a unique color according to the manufacturer of the router. The links are bisected and displayed in a color coded according to the amount of reserved bandwidth, which can be manually scoped by the administrator and originated from the node to which the interface is attached based on the attached interface points of the bisected links. Indicates the directionality of the bandwidth of the path.

FIG. 25 shows the average traffic amount of traffic that has passed in the last 5 minutes, while FIG. 27 shows the amount of bandwidth currently reserved. This user interface allows the administrator to immediately see which path has the most resources reserved for the current management network, so that the path can be easily set up when setting up a new path.

FIG. 28 is a diagram illustrating an embodiment of a user interface for visualizing multiprotocol label switching (MPLS) network affinity information according to the present invention.

As shown in FIG. 28, the user interface for visualizing multiprotocol label switching (MPLS) network affinity information includes a management node, the domain name of the node and a loopback IP address 2810, on the management node. A point and IP address 2820 for an interface, a link 2830 for connecting an interface between management nodes, and a color rectangle 2840 for displaying affinity information for each interface.

Affinity information is information assigned to each interface by the multi-protocol label switching (MPLS) network manager and used to calculate a specific path. The user interface of the present invention directly monitors affinity information set in each node's interface. Visualize. In this user interface, the traffic or reservation information for a link is meaningless and therefore displayed in a single color.

FIG. 29 is a diagram illustrating an embodiment of a user interface for visualizing a multiprotocol label switching (MPLS) network physical link topology and a label switching path (LSP) tunnel relationship.

As shown in FIG. 29, the user interface for visualization of managed multi-protocol label switching (MPLS) network physical link topology and label switching path (LSP) tunnel relationships includes a managed node, the domain name of the node, and a loopback IP. (IP) address 2910, a point for an interface on a management node and an IP (IP) address 2920, a physical link 2930 connecting the interface between the management nodes, and a link representing a label switching path (LSP) tunnel ( 2940).

Label Switching Path (LSP) tunnels are intended to represent that there is a Label Switching Path (LSP) tunnel between the start and end nodes of the tunnel instead of indicating a physical path. It displays all intermediate nodes and links of the physical path and also indicates the flow direction (2950) of the path.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium.

The computer-readable recording medium may be a magnetic storage medium (for example, a ROM, a floppy disk, a hard disk, etc.), an optical reading medium (for example, a CD-ROM, DVD, etc.) and a carrier wave (for example, the Internet). Storage medium).

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

As described above, the present invention visualizes various management information of a multi-protocol label switching (MPLS) network at a glance to help make complicated management tasks conveniently and accurately to make decisions necessary for traffic engineering, thereby managing management manually or empirically. In this case, even a new administrator who does not have a high level of domain knowledge of the administrator can play the same role as an advanced administrator. Therefore, there is a significant reduction in maintenance and training costs required for network management.

Claims (9)

A resource monitoring server that collects and stores network resource state information including interface statistics, topology information, and label switching path information; A traffic measurement and analysis server for measuring, collecting, analyzing, and storing traffic data including an autonomous system traffic matrix adjacent to network performance; A proxy agent that collects router information that is not defined in the standard of the simple network management protocol and transmits it to the resource monitoring server and the traffic measurement and analysis server; A common service interface unit receiving the traffic data and network resource state information from the resource monitoring server and the traffic measurement and analysis server and transmitting the received network data to a graphical user interface unit; And A multi-protocol label including a graphical user interface for visually expressing network resource status information from the resource monitoring server, traffic information analysis information from the traffic measurement and analysis server, and information from the common service interface unit, and providing the administrator visually. Switching network management device. The method of claim 1 wherein the graphical user interface is Multiprotocol label switching network management apparatus, characterized in that can be performed in a system equipped with a Java virtual machine. (a) collecting, by the resource monitoring server, network resource status information including interface statistics, topology information, and label switching path information in a database for the resource monitoring server; (b) the traffic measurement and analysis server measuring, collecting and analyzing traffic data including network performance and adjacent autonomous system traffic matrices and storing in a database for the traffic measurement and analysis server; (c) the proxy agent collecting router related information which is not defined in the standard of the simple network management protocol and transmitting it to the resource monitoring server and the traffic measurement and analysis server; (d) receiving, by the common service interface unit, traffic data and network resource state information from the resource monitoring server and the traffic measurement and analysis server and transmitting the received network data to the graphical user interface unit; And and (e) a graphic user interface unit receiving the traffic data and network resource state information of the network from the common service interface unit and visually presenting it to the administrator. The method of claim 3, wherein step (e) (e1) Displays menu information for operating the management system in the operator's operating environment in the first area of the window and displays the label switching path information found by the function of creating, modifying, deleting, and automatically finding multiprotocol label switching for traffic engineering. Presenting the second area within the window in tree form; And and (e2) displaying the topology of the management network in a third area of the window according to selection information selected from an administrator in the view menu of the management system operation menu information. The method of claim 4, wherein if the label switching path traffic statistics view is selected by the administrator in the step (e2), The domain name and loopback IP address of the managed node and node representing the actual routers present in the management network; Point and IP address for the interface on the managed node; A link connecting an interface between management nodes; And A method for managing a multi-protocol label switching network, comprising a numerical value indicative of the average amount of traffic for the last five minutes imposed on each link in a third area of the window. The method of claim 4, wherein the resource reservation view is selected by the administrator in the step (e2), The domain name and loopback IP address of the managed node and node representing the actual routers present in the management network; Point and IP address for the interface on the managed node; A link connecting an interface between management nodes; And A method for managing a multi-protocol label switching network, comprising a numerical value indicative of the amount of bandwidth reserved for each link in a third area of the window. The method of claim 4, wherein if the preference view is selected from the manager in the step (e2), The domain name and loopback IP address of the managed node and node representing the actual routers present in the management network; Point and IP address for the interface on the managed node; A link connecting an interface between management nodes; And Multi-protocol label switching network management method characterized in that the network manager displays a color figure indicating the preference information used when calculating a specific path for each interface in the third area of the window. The method of claim 4, wherein the link and tunnel view is selected by the administrator in the step (e2), The domain name and loopback IP address of the managed node and node representing the actual routers present in the management network; Point and IP address for the interface on the managed node; A link connecting an interface between management nodes; And And a label switching path tunnel link in a third area within the window to indicate that there is a label switching path tunnel between the start node and the end node of the tunnel. A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 3 to 8.