DE19947083A1 - Configure a telecommunications network with multiple network regions - Google Patents

Abstract

Configuration of a telecommunication network with several network regions by means of a management network comprising an NMC and at least one OMC for control of each network region comprises a) sending a command file (UKD) from the NMC to an OMC of a network region in a command syntax independent of network region (tkd), b) converting the command file (UKD) into a region specific script file (SCD) by means of the OMC and c) sending the script files (SCD) to network elements (BSS) in the network (tsd) for said network elements to execute.

Description

The invention relates to a method for configuring a Telecommunications network with several, in network regions together network elements through several management levels Management network with at least one network management ment center for central monitoring of the network, at least an operation and maintenance center for monitoring and Control of an assigned network region and the Network elements, in which within each network region between at least one operation and maintenance center and commands containing at least one network element messages according to a message syntax specific to the network region be replaced.

Modern telecommunication networks, for example mobile radio networks usually include a large number of switches transmission and transmission components; these will in accordance with the Inter national telecommunications association (ITU) in the following as Network elements (NE, "Network Elements") referred to. For the The task of comprehensive overall control of the network elements a telecommunications network with regard to operation, administration tion and maintenance (OAM, "Operations, Administration and Main tenance ") see various ITU standards, in particular the recommendations M.3010 and M.3100, an independent, information processing management network (TMN, "Telecommuni cations Management Network "), which includes the Network elements belong as end points and which via stan standardized interfaces and protocols access to the network has elements, of which there are control-relevant messages receives and which it manages and controls.  

The principles of a management network, also known as TMN Principles are defined, define multiple management Levels for the management of a telecommunications network, where each level has a dual function. For one thing each level except the bottom has a manager role for that underlying level; on the other hand, every level except the top an agent function for the next higher level. The management levels include at least one network facility level ("Network Element Level") with usually more ren network elements - such. B. in the case of a cellular network several base station systems -, one network device management level ("Network Element Management Level") with at least one, but often a number of operating and Operation and Maintenance Centers, OMC), as well as a network management level ("Network Management Level ") with at least one network management center (" Network Management Center ", NMC).

Linking the operations and maintenance centers to the Network management center on the one hand and with an intermediary len the telecommunications network on the other hand with Using the so-called Q3 interface. The Q3 interface was specifically defined for this purpose, cf. the mentioned ITU recommendations M.3010 and M.3100 as well as the ITU Recommendations X.710, X.711 and X.226 referenced.

An essential functional area of network management is the configuration management ("Configuration Management"), that defines a set of services that change the Structure and thus the behavior of telecommunications enable network by the network operator (operator). This Services always refer to instances of managed ones Objects that collectively contain the network-specific management information formation base (MIB). A managed object is one logical abstraction of a resource in telecommunications network. A distinction is made between hardware-related managed objects, which is a manufacturer-specific reality  Describe a function, and function-related acc gnawed objects, each of which is abstraction manufacturer-neutral functionality. To the object oriented modeling are object classes ("Managed Object Classes ") is used.

The configuration management of a telecommunications network such as B. a cellular network is usually done by two manager pages, namely either centrally on the Be drive and maintenance center or "on site" using a Maintenance facility, a so-called "local maintenance Terminal "(LMT), which is attached to various network elements can be closed. Configuration changes with the help of the OMC or LMT facilities have the disadvantage that they affect only a limited part of the entire network. Because an LMT facility only allows access to that network elements to which they are connected. The configurati ons changes by an operations and maintenance center are carried out on the basis of manufacturer-specific procedures for the network belonging to a network region elements. Because a telecommunications network is usually systems from different manufacturers with often very different Operating concepts includes, is at least a corresponding one Number of operations and maintenance centers required. On another disadvantage is that configuration changes over these facilities only take place at the times when these are staffed, and thus especially to Fei days or are not possible on weekends.

Monitoring of the telecommunication network from the network measure management center from is known; the implementation of confi guration changes by means of the network management center however not known as this involves considerable effort would be connected. For example, on unpredictable events To be able to react quickly, it is necessary that the operators of the network management center also the configura network regions, under certain circumstances even  the configuration of several network regions at the same time. Due to the manufacturer's different operation the operation and maintenance centers would therefore need the network mana gement operators a corresponding number of command speech dominate what a network operator due to the associated costs (personnel, training, etc.) unacceptable is tabular.

It is therefore an object of the invention to show a way the execution of parallel configuration changes calls from a higher-level network management center the Q3 interface and over a number of operating and Maintenance centers that come from different manufacturers can, allowed.

This object is achieved by a method of the type mentioned at the outset, in which:

• a) from the network management center one in one of the networks regions-independent command syntax File containing at least one command related to the conf guration of network elements, to an operating and Maintenance center of a network region is transmitted,
• b) received by the operating and maintenance center a command file in a script file with at least one Command according to the message syntax of the network region is specific, is converted and
• c) the script file, or at least the one it contains ne (n) command (s), transmitted to network elements of the network region and carried out by them.

This solution allows the implementation of network regions far-reaching configuration changes without the operator the network management center with knowledge of command practice of the OMC or LMT facilities. In addition the central change control now turns the risk significantly reduced that configuration changes in ver  different network regions to differing, eventu ell incompatible configurations.

In a preferred embodiment of the invention favorable feedback to the network management center, and subsequent to step c) (as a step d)) on the part of the operation and maintenance center one of those Report report sent to at least one network element the execution of the script file or the one contained therein Receive commands (s), based on which a result message generated and sent to the network management center.

It is advantageous to possibly in the command file intercept contained errors, which, for example, reflected verbal configuration results in neighboring network regions could result before submitting the script file A plausibility on the part of the operating and maintenance center Checking of the commands contained in the script file carried out, and only if the result of this test posi tiv, the script file is transmitted to the network elements becomes.

Furthermore, it is advantageous if the Command file from the network management center tion message is sent, which a unique Trans Detection to identify the configuration process contains associated messages, and this transfer identifier in the following between the network management center and the operating and maintenance center and the Messages related to the configuration process is included.

A method is particularly useful for checking the plausibility of a command file for use in a configuration method according to the invention, in which:

• a) from the network management center to the command file Operation and maintenance center of a network region transmitted becomes and on the part of the operation and maintenance center
• b) the command file received in this way into a script file at least one command according to the message syntax that the network region is specific, is converted,
• c) a plausibility check of the one in the script file contained commands (s) is carried out and
• d) based on the result of the plausibility check Result message generated and this to the network management center is sent.

Here it is again favorable if before the transmission the command file from the network management center tion message is sent, which a unique Trans Detection to identify the configuration process contains associated messages, and this transfer identifier in the following between the network management center and the operating and maintenance center and the Messages related to the configuration process is included.

It is further to carry out a configuration on the one hand and a plausibility check for the configuration On the other hand, implementation in a uniform manner can, advantageous if the initiation message a Contains mode parameters, which of the operating and war center is evaluated, and after the conversion of the Command file in a script file due to the mode parameter either a configuration change using the script file started or just a plausibility check is carried out.

A particularly useful implementation of the invention for the configuration of as a base station system Realized network elements implemented network elements.

The invention is illustrated below with the aid of an embodiment game explained in more detail, the attached figures to be pulled. These show in schematic form:

Fig. 1 is a management network with three levels of management;

Fig. 2 the processing of a configuration change according to the invention in the management network of Fig. 1 and

Fig. 3 is a signal flow diagram of the messages exchanged between the network management center and the operation and maintenance center of Fig. 2.

The exemplary embodiment relates to the configuration change in a cellular network, which operated according to the GSM standard and in which the TMN concepts are implemented. Of course, the invention is not on GSM networks limited, but can be limited to other networks, the one Use management, apply equally.

In a mobile network, the participants have mobile endge councils, the mobile stations. These mobile stations communicate with radio stations via a radio interface, which are called base stations. The base stations each supply those in the radio area of a radio cell located mobile stations. They are preferably for abdec of a larger radio area summarized and with Base station controls connected. The base stations and Base station controls belong to a base station system ("Base Station Subsystem") of the cellular network. The base sta tion controls communicate via defined interfaces with one or more switching devices of the network, the mobile switching centers, via which the Transition to other telecommunication networks takes place. The Mobile switching centers form together with a number of databases the switching system ("Switching Subsys tem ") of the mobile network.  

Regarding the control of the network devices mentioned Operation, administration and maintenance are components a management network one or more operating and war centers, each with a base station system or switching system over a defined cut communicate.

Several levels are defined in the management network for configuring the mobile radio network, of which three levels A, B, C are explained below in the present example with reference to FIG. 1. The lowest level C of the management network is from the base station systems BSS, BS2,. , ., BSk,. , ., BSm and referred to as the "Network Element Level". In other embodiments of the invention, switching centers, routers or microwave devices, for example, can be managed as network elements, provided that these devices support a corresponding interface of the management network, in particular a Q3 interface.

The next management level B is the network element management level. In this two 1 operating and was OC2 BSS BSm in Fig exemplary processing centers OMC shown that sisstationssysteme their associated Ba provide the manufacturer-specific Manage ment functionality. the base station systems of an operating and maintenance center represent a network region in the example shown. In addition, the network management level ("Network Management Level") resides with at least one network management center, which in each case implement an integrated management functionality for the network operator that is independent of the manufacturer. In Fig. 1, only a network management center NMC is shown; however, several network management centers can also be provided in a telecommunications network, e.g. B. to perform different management tasks. The NMC network management center is connected via Q3 interfaces to the OMC, OC2 operating and maintenance centers assigned to it.

It should be noted at this point that the term Network region here less geographical than organisa has toric meaning. A network region has at least one Network element, but usually several network elements and usually a network element belongs to only one network region. In special cases, the network regions can overlap, as well as several Be in a network region drive and maintenance centers can be provided.

The following explanations only refer to the Base station system BSS or the operating and maintenance center trum OMC, but apply equally to the others Base station systems BS2-BSm and operating and maintenance centers tren OC2 of the network.

Each network management center NMC, each operating and maintenance center OMC and each base station system BSS each have a control device NST, OST, BST and a storage device NSP, OSP, BSP connected to the control device in question. They also have (not shown in FIG. 1) transceivers for sending and receiving messages and information about the interfaces between the different management levels. The message and information transmission takes place on the Q3 interface between the network management center NMC and the operation and maintenance center OMC according to a defined object model and on the interface between the operation and maintenance center OMC and the base station system BSS according to another, usually manufacturer-specific object model.

According to the invention, a configuration change for the base station systems BSS-BSm from the network management center trum NMC, for example through a menu-driven input  be by the network management operator via a user interface area of the network management center NMC. The tax facilities and storage facilities take over in the be relevant management component during the configuration process control and storage functions.

With reference to FIG. 2, the operator enters the desired configuration changes on a terminal NMT via a menu-controlled user interface UIF provided by the network management center NMC. The operator can also use symbolic names that are valid throughout the network to select the object instances to be reconfigured. By using a menu-driven interface, possible input errors, e.g. B. with regard to the selection of the configuration parameters to be changed and their permissible values, largely avoided. The software of the UIF user interface generates a corresponding command line from each configuration change of an object instance in accordance with a simple syntax, which is independent of the manufacturers of the operating and maintenance centers OMC. The configuration changes are collected and, as soon as the operator has finished the entry, stored in a manufacturer-independent command file UKD. The command file thus contains the configuration changes in a syntax that is neutral to the manufacturer or network region, advantageously in ASCII format.

In the next step, the transmission tkd of the command UKD file from the NMC network management center to the and maintenance center OMC prepared. The operator can here select the name of the command file for one, if several command files - for example, previously created Command files - on the part of the NMC network management center are stored, on the other hand determine the execution mode. Possible execution modes are in particular a test mode ("check mode"), in which the in the command file UKD specified configuration changes on the part of the operating and maintenance center OMC only for plausibility  be checked, and a run mode to the actual Execution of the changes. If the running mode is selected the operator can also set a time for the Specify execution of configuration changes; otherwise the changes are carried out immediately or in terms of checked the plausibility.

The signal flow diagram of Fig. 3 shows the message flow over the Q3 interface between the network management center NMC and the operation and maintenance center OMC of the invention. The messages follow the standardized, generic procedures of the CMISE service ("Common Management Information Service Element") in accordance with ITU standard X.710. Furthermore, a standardized application element FTAM ("File Transfer Administration and Management") is used on the Q3 interface to support the exchange of files and the processing of file segments.

The message exchange is initiated by the network management center NMC by means of an introduction message, for example a CMISE-standardized M-ACTION message of an action type "requestChangeConfiguration" (request for the configuration change). This M-ACTION message, which in the exemplary embodiment serves as an introduction message, contains the following further parameters as action information:

• - the file name of the selected command file UKD,
• - the execution mode,
• - if applicable (see above) the time of execution, such as
• - a transfer identifier ("transfer id").

The transfer identifier serves as a unique, through the network mana NMC center for identification and Correlation of the subsequent messages, which in the course of the Exchange of messages between the NMC network management center and the OMC operations and maintenance center the command file UKD are sent. By the clear  Transfer identifier is a unique assignment of the messages possible to the command file, which for example a not An agile requirement is if there are several configuration changes stanchions run in parallel.

Subsequently, the tkd of the command file UKD is transmitted using a standardized, CMISE-controlled FTAM file transfer, cf. the standard ETSI GSM 12.00. On the part of the NMC network management center, an M-ACTION message with the "requestTransferDown" action type (request for downward transfer) is sent to the OMC operation and maintenance center, which parameters include the file name of the command file and the transfer identifier as in the Initiation message inn specified, as well as information regarding the required storage space. In Fig. 2, on the part of the network management center NMC and the operation and maintenance center OMC, the functional elements ntk, otk are symbolically shown, which implement the functions for transmitting the command file UKD. The operating and maintenance center OMC checks the available free space and, if this check is positive, the readiness to receive the file is indicated by means of an M-EVENT-REPORT message with the action type "transferDownReady" (downward transfer ready). This message in turn contains parameters such as the file name of the command file and the transfer identifier. Then the network management center NMC establishes a logical connection of the FTAM service - so-called "FTAM association establish ment" - and in this connection FTA the command file UKD is transmitted to the operation and maintenance center OMC by means of the FTAM service. At the end of the file transfer tkd, the network management center NMC sends an M-ACTION message of the action type "transferDownComplete" (downward transfer complete), which also contains the file name of the command file and the transfer identifier.

Referring back to FIG. 2, after successful receipt of the command file UKD, the operating and maintenance center OMC converts each command line of the file UKD into a command which, according to the syntax of the OMC's own - manufacturer-specific - command interface, the so-called CLI ("Command Line Interface"), is formed. The CLI commands generated by the operation and maintenance center OMC by means of the command conversion kdk are collected in a so-called script file CCD ("script file"), each CLI command forming a line of the script file.

If a command in the command file UKD contains a symbolic one Names instead of an instance address, for example this in the conversion kdk by a corresponding Se RDNs (Relative Distinguished Names) replaced. These are taken from a symbol table STB, which assignment contains symbolic names and RDNs. The Ver RDNs are used in accordance with ITU-T standard X.720 and serve the object addressing by means of a so-called "naming tree ". An RDN gives the address of an object instance relative to the next higher level ("containing") instance on. A sequence of several RDNs forms a so-called FDN ("Full Distinguished Name"); an FDN gives the object address relative to a global root. Only one FDN is assigned to a symbolic name.

After converting the command file kdk, the finished, OMC's own script file SCD from the CLI driver clh des Be drive and maintenance center OMC. Here the depends further processing based on the finished OMC script file SCD from the value of the inn Execution mode specified as a parameter. Is the Run mode specified, so are in the script file contained CLI commands from the CLI driver to their plausi bility checked, and then if the test is successful is rich, the script file is assigned to the assigned base BSS systems. The transfer tsd to the  Base station systems BSS is carried out on the basis of this see method and is not the subject of the invention.

The base station systems BSS maintain the in the file SCD specified configuration changes in a known manner - If an error occurs, the further bear processing of the script file aborted - and finally send a corresponding report report to the company and Maintenance center OMC back. Because of the reports becomes one on the part of the operating and maintenance center OMC Result message rmg generated and sent to the network management center trum NMC sent, for example, by its own function element smg.

If, on the other hand, the test mode is specified, then those in the Script file contained CLI commands only on their Plau checked for sensitivity; a transfer tsd the script File commands to the base station systems BSS are omitted however. Instead, the CLI driver clh becomes a plausible Liability message pmg generated, which for the further process the place of the report report (s) bmg occurs. Same ge happens in run mode if the plausibility check is negative is.

Due to the test mode, the operator has a network mana center NMC the possibility of checking a Command file before the file is ready for execution this is provided immediately or after a time, released.

The result message rmg is e.g. B. an M-EVENT-REPORT- Message of the action type "resultschangeConfiguration" (Re results of the configuration change), which in addition to the Trans Detection of the associated initiation command within one Has error parameters as well as a text parameter. The In turn, the transfer identifier serves to clearly assign the Message rmg for a command file UKD. The text parameter serves in the event of an execution or plausibility  error specifying the command that triggered the error has, and contains this command z. B. in the original format of the command file UKD. The error parameter specifies the errors that have occurred, e.g. B. in plain text format; were the It contains configuration changes successfully a corresponding message such. B. "No error". The Resul rmg is sent by the network management center NMC emp catch and the operator, for example, about the users interface UIF, NMT displayed.

An example of a simple, manufacturer-neutral syntax for use in a command file UKD according to the invention is shown below with reference to the syntax diagrams in FIG. 4. The syntax is based on the principles of the so-called MML defined in ITU-T standards Z.314 ("NML - The Character Set and Basic Elements") and Z.315 ("MML - Input (Command) hanguage Syntax Specification") - Syntax ("Man Machine Language"). The elements of the syntax are reproduced in English in accordance with the ITU-T standards mentioned.

The definition of an MML command "command" according to ITU-T Z.315 is shown in Fig. 4a, and thus consists of a command code "command code", which - in each case after a colon ":" - one or more parameter blocks " block of parameters "can follow. The command code - FIG. 4b - is composed of one to three identifiers, which are each connected by hyphens "-". The order of the components within the command code is not standardized. In the syntax presented here, the command code contains two components: an action and an object class, which are connected by a hyphen according to Z.315.

Fig. 4c shows the definition of the parameter block "block of parameters", where only the branch 2 is needed; Thus, a parameter block consists of a comma "," separated list of name-defined parameters "parameter name defined parameters", which according to FIG. 4d consists of a parameter value "parameter value", if necessary, a parameter name "parameter name" and an equal character "=", exists.

A single parameter block is used for the syntax proposed here; so that the following form of command results:
action object class: parameter block;

There is a name-defined para in the parameter block meter MOI is mandatory as explained below. The Be For example, the following keywords will result in a malfunction restricted: create, set, get and delete.

The object class component defines the class of the currently used object (object instance) and adopts one of a group of predetermined keywords, which corresponds to the information model of the interface between the network management center NMC and the operation and maintenance center OMC. The parameter MOI, which must appear in the parameter block, defines the currently used object. In any case, the parameter name "parameter name" assumes the fixed value MOI; the parameter value "parameter value" follows the syntax as in Fig. 4e-h. The following cases are permitted for the parameter value:

• a) Composite parameter "compound parameter argument" with deci "decimal numerals": This characterizes the full permanent address path from the global root ("global root") in Form a sequence of decimal numbers, which are separated by dashes are separated.
• b) Composite parameters "compound parameters argument" with symbo symbolic names and decimal numbers numerals ": The symbolic name corresponds to that in basic states "BSS symbolic names" and can be used as such as in case a) replaced part of the address path Zen.  
• c) Simple parameters "simple parameter argument" with symboli "symbolic names".

The use of further parameters depends on the respective used action type. For example, if the command set is used, there is at least one additional parameter ter mandatory and specifies the attribute, its value with by means of the set command. Other parameters are if desired, possible, e.g. B. to meh with a set command change other attributes. The parameter name is the name of the relevant attribute according to the information model on the Q3 interface between network management center NMC and Be drive and maintenance center OMC. The parameter value is the new value saved by the specified parameter name should take the specified attribute.

The described syntax is only due to the usage a subset of the structure defined in ITU-T Z.315 simple enough that they also open in a simple way an already known network management center or others Management network centers is feasible. It is advantageous here in particular that the command code action from a limited set of a few keywords which is based on the command keywords of the CMISE Lean on services. It is also advantageous that the Syntax the use of network-wide - namely both the network management center NMC as well as the operational and Maintenance center known OMC - symbolic name under that supports a full addressing path or also can only replace part of an addressing path.

The invention allows the confi cross-network regions guration changes, the operator of the network management NMC center no knowledge of the manufacturer or network region must have specific command languages. By ver Using a menu-driven interface can be possible Input errors, e.g. B. with regard to the selection of the to be changed  Configuration parameters and their permissible values, widely be avoided. The exchange of messages between Network management center NMC and operation and maintenance center OMC, in particular the transmission tkd of the command file UKD, takes place in the context of known application elements of the Q3 Interface, e.g. B. the CMISE and FTAM services, what a Implementation of the invention on any management system men significantly relieved. The via the network management center NMC entered configuration changes of the Telekommunika tion network, especially the mobile network, according to the Invention by the operation and maintenance center OMC in the same way as commands from the local OMC or LMT operators checked for plausibility. Furthermore is it is possible that several operators of network management centers NMC at the same time configuration changes in the network execute regions. By using a point in time Parameters is the deferred execution of configurations ons changes possible, for example to a predetermined ba later, later.

Claims (8)

1. Method for configuring a telecommunications network with several network elements combined in network regions (BSS, BS2,..., BSk,..., BSm) through a management network with at least one management level (A, B, C) Network management center (NMC) for central monitoring of the telecommunications network, at least one operating and maintenance center (OMC, OC2) for monitoring and control of a network region assigned to the operating and maintenance center (OMC, OC2) and the network elements (BSS-BSm), whereby in each case between an operating and maintenance center and at least one network element of the assigned network region, messages which contain commands in accordance with a message syntax specific to the network region are exchanged, characterized in that

• a) from the network management center (NMC) a command file (UKD) written in a command syntax independent of the network regions, which contains at least one command relating to the configuration of network elements, to an operation and maintenance center (OMC) of a network region (tkd) will
• b) the operating and maintenance center (OMC) converts (kdk) the command file (UKD) received in this way into a script file (SCD) with at least one command according to the message syntax that is specific to the network region, and
• c) the script file (SDC), at least however the command (s) contained therein, is transmitted (tsd) to at least one network element (BSS) of the network region and is carried out from there.

2. The method according to claim 1, characterized in that subsequently

• a) the operating and maintenance center (OMC) receives a report (bmg) sent by the at least one network element (BSS) regarding the execution of the script file (SDC) or the command (s) contained therein, on the basis of which one Result message (rmg) generated and this is sent to the network management center (NMC).

3. The method according to claim 1 or 2, characterized in that before transmission (tsd) the script file (SDC) from the operating and war tungszentrum (OMC) a plausibility check by the Script file containing commands (s) is performed, and only, if the result of this test is positive, the script Parti is transmitted to the network elements. 4. The method according to any one of claims 1 to 3, characterized in that before transmission (tkd) the command file from the network management center (NMC) an initiation message (inn) is sent, which is a unique transfer identifier to identify the confi guration process associated messages, and that this transfer identifier in the subsequent between the network management center (NMC) and the operational and war center (OMC) and the relevant confi messages associated with the guration process. 5. Method for checking the plausibility of a command file (UKD) for use in a method according to one of claims 1 to 4, characterized in that

• a) the network management center (NMC) transmits (tkd) the command file (UKD) to an operation and maintenance center (OMC) of a network region and the operation and maintenance center (OMC)
• b) the command file (UKD) received in this way is converted (kdk) into a script file (SCD) with at least one command in accordance with the message syntax that is specific to the network region,
• c) a plausibility check of the command (s) contained in the script file is carried out and
• d) a result message (rmg) is generated based on the result of the plausibility check (pmg) and this is sent to the network management center (NMC).

6. The method according to claim 5, characterized in that before transmission (tkd) the command file from the network management center (NMC) an initiation message (inn) is sent, which is a unique transfer identifier to identify the confi guration process associated messages, and that this transfer identifier in the subsequent between the network management center (NMC) and the operational and war center (OMC) and the relevant confi messages associated with the guration process. 7. The method according to claim 6, characterized in that the introduction after contains a mode parameter, which of the Operation and maintenance center (OMC) is evaluated, and that after converting (kdk) the command file into a Script file either a confi due to the mode parameter guration change started with the script file or le only a plausibility check is carried out. 8. The method according to any one of claims 1 to 7, characterized in that it is for configuration tion of as base station systems of a mobile radio network lized network elements is executed.