SE514989C2 - Method and device for ATM networks - Google Patents

Abstract

The present invention relates to an ATM-network in which a central controlsystem (NMC) and agents controlling the switches interact in order to establish a connection. Information about a second subscriber with whom a first subscriber wishes to establish a connection is transmitted from the first subscriber to the agent of the switch to which the first subscriber is connected. The information is passed on to the central control system, which indicates a path between the subscribers, whereafter the connection between the subscribers is set up by the agents. The connection may involve more than one ATM-switch.

Description

30 514 989 2 between two customers. A customer must specify exactly how links should be cross-linked in cascade (from-point-to-point) and can not e.g. enter two public addresses and then let the network handle the connection. The customer must know exactly how links are to be created through the network and cross-linked with each other, from customer interface to customer interface. This is a problem with the Internet's SNMP, which was specified for point-to-point manipulation and not network management.

As a way to be able to reuse M3 specifications and supplement these with a system solution, you can easily go from an M3 for element management to an M3N (N = network) for network management. Such a modified M3 can only be offered to operators as well as customers accustomed to SNMP.

U.S. Patent No. 5,185,860 discloses a method for mapping the presence of nodes (elements) in a network in a general manner. The method that requires TCP / IP uses SNMP. Some nodes in the network are called "Discovery Agents" and these keep track of the presence of other nodes in the network. When mapping the network, these nodes are requested in order to obtain information about the network's topology. This information is then stored in a central memory, whereby the system requests each of the detected nodes if these are also Discovery Agent. The results are stored in a central database which can then be used by e.g. "Network Manager". The database is kept up to date through periodic surveys.

EP 621706 describes a system and method that allows a manager in an SNMP environment to collect updates from agents in the system. This is accomplished by providing the agents' tables with information on current audits.

U.S. Patent No. 5,289,468 discloses a "Network Management" for local area networks (LANs) that are interconnected to another network, such as a WAN. The method is based on SNMP.

U.S. Pat. No. 5,339,318 describes "Management" in an ATM network.

The network includes "Network Management Units" that maintain a table of VCIs (Virtual Channel Identifiers) and VPIs (Virtual Path Identifiers). 10 15 20 25 30 35 40 514 989 3 DISCLOSURE OF THE INVENTION Technical problem The present invention intends to provide a solution in which central control systems handle connection between different users in an ATM network. In the systems used so far, the user has had to specify which links are to be used in the ATM network. The user is hereby required to know the connection procedures and current nodes that are to be used in a connection.

THE SOLUTION The present invention relates to a method of ATM network in which ATM network a central control system is arranged. Information from a first subscriber is transmitted to the control system regarding a desired communication with a second subscriber. The control system receives the information from the first subscriber. The control system communicates with agents in the network. The agents find out which ports are in a switch connected to the agent. Furthermore, the agent finds out which ports are occupied and which connections are set up between different switches in the system. The agents establish a communication path in the network between the first and second subscribers. The connection is established in the network, whereby the subscribers are allowed to communicate with each other.

In a further development of the invention, the agents control switching functions in the network. The agents also notify the control system of which roads and connections are available.

The control system orders the agents to set up designated connections and interconnection of these. Each of the agents controls a designated switch in the network. The agents arrange the necessary connections in the switches in the network. The control system notifies the agents which connections, roads and ports are to be used for connections between the subscribers. The control system orders connection between the subscribers in the network where several of the agents and exchanges are involved.

In the network, exchanges are arranged and the exchanges are controlled by agents. Information from first subscribers is transferable to the agents in connection with the establishment of communication between the first subscriber and the second subscriber. A central control system is arranged in the ATM network. Information from the subscriber, regarding desired communication with a second subscriber, is transmitted to the central control system. The central control system is arranged to indicate a route choice between the subscribers in the ATM network. Said route choice is connected between the subscribers, communication between them is allowed.

The central control system is arranged to establish a connection between the subscribers over a plurality of the exchanges.

The central control system is arranged to communicate with the agents. The central control system indicates addresses to / from which communications are to be established. The agents are arranged to order connection for communication set-up in the ATM network. The agents are further arranged to notify the central control system whether the gear in question is capable of establishing a desired connection or not.

BENEFITS The proposed solution gives users in an ATM network the opportunity to specify a subscriber with whom they want to communicate. The network then takes care of the connection between the respective subscribers. Central control bodies in the system take care of the connection and disconnect the subscriber from the work of finding out addresses and connection paths in the network. In this way, the connections in the network become easier and even faster than if the subscriber himself were to find his way around the network.

Furthermore, the subscriber does not need any special knowledge of the network structure and connection procedures therein.

DESCRIPTION OF THE FIGURES Fig. 1 shows a system with M3. With M3, the customer NMS (Network Management System) can ask the operator CNM (Customer Network Management) to cross-connect port A to port B on the ATM exchange. However, the customer cannot request a connection through several exchanges in a large ATM network. With the system solution, this is managed by CNM called NMC (Network Management Center). (which is a subset of what in the text Fig. 2 shows part of the objects defined in RFCl695.

Fig. 3 shows a scenario to illustrate the role of NMC and how it can use M3N to control an entire ATM network consisting of standard components.

Fig. 4 shows tables in NMC for M3N. DETAILED EMBODIMENT In the following, the invention is described with reference to the guras and the designations therein.

I fi g. 1 shows how M3 (M = Management, 3 = Manager interface no. 3) how the customer NMS (Network Management System) can ask the operator CNM (Customer Network Management) to cross-connect port A to port B on the ATM switch (ATM = Asynchronous Transfer Mode) in the traditional case, however, the customer cannot request a connection through fl your exchanges in an ATM network. Setting up connections over one or more of your switches is in this case handled by a CNM agent. CNM consists of a subset of NMC (Network Management Center). A user who wishes to set up a connection enters the address / addresses of the desired party (s) in a communication. The information is received by the control system, which then contacts current agents in the system. The agents then notify the control system whether or not the desired connections can be made in the network. With the proposed solution, no changes are required in network elements other than in the central support system (NMC) where the system solution is to be implemented.

M3N (M = Management, 3 = Management Interface No. 3, N = Network) initially has references to at least one SNMP agent (SNMP = Simple Network Management Protocol that implements M3, ie ATM forum standard M3).

Through the agent, M3N can obtain information about which other agents the company that controls neighbor switches to the exchange that the agent controls. The M3N system can, for example, contact agents and read its atmInterfaceColff able (see fi g. 2).

EXAMPLE See fi g. 3. NMC has the address of agent l which controls ATM exchange l. It contacts agent l (with SNMP) and reads all elements in its atmInterfaceConfT able (fi g. 2) NMC then sees that exchange 1 has a direct connection to - ATM- gear 2 controlled by agent 2.

- ATM switch 3 controlled by agent 3.

NMC now stores this fact in atmTopologyTable (fi g. 4) and repeats the procedure with agent 2 and agent 3 until it finds no new ATM switches.

This procedure of mapping all agents, and indirectly also the topology of ATM switches, can thus be done by the M3N platform (NMC) or manually. In the latter case, the operator himself enters information about which switches the ATM network consists of, which SNMP agents the switches are controlled by, and how they are connected to each other. The system solution is to specify four tables in NMC that NMC can use to keep track of the inter-relationship between agents in the network that are controlled by M3. From these tables, the customer gets access to one, through which he / she can request that a VP be connected between two UNI (User Network Interface), ie two customers. The customer requesting connection and the customers being connected do not have to be the same, so the M3N method can be used as a service by different operators (eg to allow an organization to subscribe to resources in an ATM network provided by an operator). In this case, the customer is given the opportunity to control how these resources are to be used. The organization can e.g. choose to have a central administrator set up a liaison between members of the organization.

Assume that customer A wants to establish a connection to customer B. Through the operator's care, the customer does not need to find out what happens in switches along the road between A and B. Instead, the customer sends SNF requests to NMC with a request as follows. [Customer A -> NMC] GetRequest (Next xclndex) to find out the next available index in uniUNITable in accordance with the standard version in SNP. The answer is obtained from NMC, ie xclndex (in the example xclndex = 3), is then used to create a new row in uniUNITable.

[Customer A -> NMC] SetRequest (3, 1.2, 4.1), ie create a new connection between port 2 on exchange 1 and port 1 on exchange 4. The combination port / exchange is expressed with ITU E. 164 addresses (ISDN number ).

With the solution in NMC, M3N will then ensure that the correct cross-connections take place in the network, whereby customer A receives the answer.

Response (3, 1.2, 88, 4.1, 77 (ie VP no. 88 can be used by customer A to communicate with customer B.

Before the reply can be sent, however, NMC must ensure that the link between the customers is established. First, they look in atnTopologyTable to find a path (eg the shortest or cheapest, or the one with the most bandwidth). In the example, we assume that NMC chooses the path l-3-4. NMC then contacts agents 1, 3 and 4 and cross-links each ATM exchange in cascade or in parallel.

It first asks agent l to find a port on switch 1 leading to switch 3. it cross-links with a VP reserved for customer A. If NMC then reserves this VP and the cross-connection is accepted by agent l, NMC creates a new row in the table uniNNITable ( NNI = Network-to-Network Interface) contains information about one of the cross-connections for SOIH xcIndex = 3. The procedure is repeated, the tables for NM3 obtain the appearance according to Fig. 4.

A device according to the invention is used in an NMC for controlling ATM networks. Since the number of NMCs with M3N will be small, an operator can invest in implementing the system solution himself. Any additional costs will be offset by the fact that it is possible to purchase standard components without requiring the addition of special solutions from suppliers. You thereby become more independent of the choice of supplier.

The invention will also be able to be used as LAN administrators who can easily set up liaison without caring about the internal structure of the network.

The system solution is thus based on a combination of M3 elements and the handling of simple tables by the telecommunications administrator.

The invention is not limited to that described above or by the claims, but may be subject to modifications within the scope of the inventive concept. 514 989 8 Appendix A This appendix contains descriptions of the figures according to drawing appendices.

FIGURE 1. M3. customer operator support system support system /: 1 1 1 1 * ï ï -_-- \ \ _....._._._-___ .. fi CNM = Customer Network Management _ NMS: Network Management System ATM interface to the customer yet- ___- II-- mm? - ATM cells ATM cells Operator ATM switch With M3, the customer's NMS (Network Management System) can ask the operator's CNM (Customer Network Management) to cross-connect port A to port B on the ATM- the switch. However, the customer cannot request a connection through several exchanges in a large ATM network. With the system solution, this is handled by CNM (which is a subset of what in the text is called NMC, Network Management Center). 514 989 q FlGUR 2. Some of the objects defined in RFC1695.

... W For elements whose ifïype = 37 (ATM) is used in fl ndex for other complementary ATMs. specx fi ka tables too. The table on the left exemplifies a system with an Ethemet interface and two ATM ports - The table on the left contains ° atmTraf fi cDescrParamTable. _. _ 2 2 2 ii Sïílïkšåaäïlïïïïsïïlåa "åïfvïšö ß l- - 1- atmTrafiiciâescrParamlndex_ .. _ raw fi * if ¶ VPL. š Pointer to descriptors above for characterization 'å' å 'å H of the traffic over VPLi both directions E 7-5 E The table on the left L k contains information about atmVplTable VPL and is indexed by Same host àifln x _fl d tmv N_ H iflndex (for to identify rn ex, a _p pimsaus ... à - r _ ~ - recerveTlratficDescrlndex, porten p Vaxe n) and VP '“transmit raf fi cDescrlndex, x atmVplCrossConnectldentifier- * L, i _ Points out a toe 8: é: é lflndexatm. .siarusm affflVPCWSSCOHHE-'Clffldex> å 'ä ä receiveTrafficDescrlndex, ï I fi bëllên below And can ä ä 9 9 transmltTrafflcDescrlndex._ Lex_ be used for: at: å: 3 ä ä atmVplCrossConnC ån _Vfiii äpm _dfir äm _dfir is cross-linked mu »t 'oe:.. <3 g IQ .g š Pointer to elements in the table with.

Q g å å å å å for portNPl som ingå 5 <<t 3 3 lkorskopplxngen. å 2- 9 2 u o ä å å 'š ._-. ° _ .ä atmVpCrossConnectTable O .9 .o E “3 å å: - i- atmVpCrossConnectIndex. å>. > g .g __lowlflndex. lowVpi å; : o __c_ __highlflndex.highVpL ... 'š ._.' .J '<5 atmVpCrossConnectlndex, g- § ___-___: i lowlllndex, lowVpi' š 'š _ highlllndex, híghVpi .... _-__ -_-_ The table above uses x = to store information about TC - (Transmission _ _ å 5 Convergence) resources The table above is indexed using 5 attnbut '_ _ such as SONET or DSS. which partly identifies the cross-connection but also the ports and vPlzn included in the cross-connection. .

The table above on the left is used as a complement to the information in ifTable. The same iflndex can therefore be used to find out general interface information (ifTacie) as well as more specific ATM information (atmlnterfacaConfTable). 514 989 H 10 FIGURE 3. Scenario to illustrate the role of NMC and how it can use MSN to control an entire ATM network consisting of standard components oa E] Customer A Customer Z Agent 4 dialed numbers indicate the number of each ATM 5 i 4 9 s 9 ill FlGUR 4. Tables in NMC for M3N.

Italic text in the tables indicates which variables are used as indexes (keys) for identifying rows in the table. , - -t-í _- z- ïšb- -1 This table contains information about which direct connections there are I a m ° P ° ° 9Y le l between different ATM switches in the network. the information in the table is actively obtained by 1 e154A 87642 In NMC (by contacting an agent and trying to freshen up all relationships recursively) or entered manually. Under the general structure of the table, examples are given of what the table could look like in a topology according to f-fig.3.

I 1 3 l Directions in the table do not matter (ie which gear is l 2 3 1 categorized as e164A and which as e164Z. Lli 3 4 i i. _ _ _ _ _ _. ..I I .. _ _ _ _ _. _ .. _, This table contains information on which switches are controlled by which aTmNUÖGPaÜY I Egents Agents can be specified by a reference (pointer) to a P arty (which contains information about the agent's IP address, I l transport protocol, any security mechanisms for authentication and i__ _ _ _ _ _ _ _ _, encryption etc)., - _ - _ _ __ __ _ _ _ _ _ ._ _. _, This table contains information about which UNl I 1 is connected to each other Additional elements can be found in xcmdex e164A VpiA 61642 vpíz I (eg _status for creating new rows) but_is not shown to have. to switch 4 / port 1. This connection has (_ _ _ _ _ _ _ _ _ _ _ _ _ _ _, VPi value 88 for customer A and 77 for customer B. i '_ _ _ "_" "" _ _ 'Gn fl iiiaiß ""' _ "" "" "'_ _' ll i pathlndex e164A vpiA e164Z vpíZ remoteParty remoteE164 remotelndex | l 3 1.2 aa 1.3 se 'agenw islls 3.1 se 3.7 ss "agents" asl å 3 4.5 5' 4.1 77 'agent4 "4 7' I ll L _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __ .i This table contains information about which point-to-punirl connections there are.The value of pathlndex is the same as for xclndex so you can easily relate a set element in uniNNlPathTable to an element in uniUNlTable. The example we assume that .NMC chooses to use the following path for establishing a VP between customer A and customer B: 1 <-> 3 <-> 4.

The specific lines for the example can all be easily related to a UNl-UNl connection through pathlndex / xclndex. oniUNlTable is actually a modified variant of atmvpCrossConnectTatle according to M3 (see previous figure). uniUNlTable is used as a reference. . -. to the actual M3 table series where the information is stored.

Claims (10)

10 15 20 25 30 35 40 514 989 ill Patent claim Device in ATM networks, in which network exchanges are arranged and the exchanges are controlled by agents, and information is transferable to the agents in connection with the establishment of communication between the first subscriber and a second subscriber, wherein a central control system is arranged in the ATM network , information from the first subscriber, regarding desired communication with one of the second subscribers, is transmitted to the central control system, the central control system is arranged to indicate a route choice between the subscribers in the ATM network, said route choice is connected between the subscribers, communication 4 them between are allowed, and the agents are arranged to command connection for communication set up in the ATM network, characterized in that the agents are arranged to notify the central control system whether the affected exchange is capable of establishing a desired connection or not. Device according to claim 1, characterized in that the central control system is arranged to establish a connection between the subscribers over a number of the exchanges. Device according to one of the preceding claims, characterized in that the central control system is arranged to communicate with the agents. Device according to one of the preceding claims, characterized in that the central control system specifies addresses to / from which communication is to be established. 5. ATM network method, in which ATM network a central control system is arranged, and information, from first subscriber, is transmitted to the control system, regarding a desired communication with a second subscriber, the control system receives information from the first subscriber, the control system communicates with agents in the network and establishes a communication path between the first and second subscribers, the agents arrange necessary connections in the exchanges in the network, the connection is established in the network, the subscribers being allowed to communicate with each other, characterized in that the agents notify the control system which paths and connections are available. that the agents notify the central control system whether the gear in question is capable of establishing a desired connection or not. Method according to claim 5, characterized in that the agents control switching functions in the network. 10 15 514 989 15 Method according to one of Claims 5 or 6, characterized in that the control system commands the agents to set up designated connections and interconnections. Method according to one of Claims 5 to 7, characterized in that each of the agents controls a designated gear in the network. Method according to one of Claims 5 to 8, characterized in that the control system notifies the agents which connections, roads and ports are to be used in connection with the subscribers, Method according to one of Claims 5 to 9, characterized in that the control system commands connection between the subscribers in the network, in which one of the agents and the exchanges is involved.