DE19837245A1 - Error detection method for ATM communications system - Google Patents

Abstract

The method involves supplying monitoring signals to the beginning of at least one monitoring path (7, 8) of the communications system when communication signals are absent. The signals are topped at the end of the monitoring path (7, 8). The monitoring path lies within an exchange (1) of the communications system. An error within the exchange is assumed when signals are absent at the end of the monitoring path. Preferably, the exchange internal monitoring signals are supplied to a first transmission line interface (2) between an external path (9) of a communication line, arranged in signal propagation direction in front of the exchange, and the exchange.

Description

The invention relates to a method for determining Errors in a communication system, especially an ATM (Asynchronous Transfer Mode) communication system, where on Start of at least one monitoring section of a communicati ons connection in the absence of communication signals Monitoring signals are fed in and at the end of the monitoring stretch out of the communication link again become. The invention further relates to an exchange device for arranging communication connections a communication system, in particular an ATM communication cation system, with a feed unit, in order at a Absence of communication signals via an active commu Nikationsverbindung monitoring signals in the communicati feed connection, and with a decoupling unit to monitor signals from an active communication decouple onsverbindung and in the absence of any Signals to trigger an error message.

From the recommendation of the International Telecommunication Union, Telecommunication Standardization Sector: "Integrated Ser Services Digital Network (ISDN), Maintenance Principles ", B-ISDN Operation and Maintenance Principles and Functions, I-610 (11/95), hereinafter briefly ITU-T Recommendation I.610 ge an ATM communication system is known in which the Communication signals are transmitted in so-called cells the. The ATM cells have a cell header, the Informa contains, on the basis of which switching facilities Network nodes of the ATM communication system recognize which of several transmission links starting at the network node the respective cell is to be sent. In the ATM communication cation systems are so-called physical and so-called virtual or ATM layers defined. In the physical Layers become ATM cells along physical transmissions  distance with clear cell-independent starting and Transfer endpoints. The virtual layers each include because of the physical layers and beyond Elements of the ATM communication system. Within the virtu The layers are virtual communication connections financed, with a virtual communication link transferred ATM cells at least once at a ver based on their cell header information the right transmission path to be conveyed.

It is known from ITU-T Recommendation I.610 to be permanent virtual connections to which the operators in particular high demands regarding their reliability be monitored as follows: The operator creates an attachment along the permanent virtual connection start point and an end point of a monitoring route. At the starting point, for example at the exit interface of a switching center and at the beginning egg ner physical transmission path is signals in the form of so-called CC cells (continuity Check Cells) in the permanent virtual connection feeds if there is no ATM Cell has arrived. ATM cells still do not arrive the starting point of the monitoring route is a CC cell into the one second each permanent virtual connection fed. This will turn on even then, a cell current is maintained up the monitoring section obtained when there are no ATM cells at the start point of the monitor arrive on the route. If there are no cells at the end point of the surveillance route can consequently point to the There is an error in the permanent virtual connection be closed. If such an error is fixed an AIS signal is forward in the signal direction (Alarm Indication Signal) in the permanent virtual connection feed. Furthermore, the operator is Alarm message informs about the presence of the error. Sol che alarm messages are particularly during the calculation  connection-dependent fees used later in an aftercare to determine at what times a permanent virtual connection was not available.

In addition to permanent virtual connections are in ATM commu nication systems also signaled virtual connections known at the request of a user of the communication cation system. Again at the request of the User or another connection participant will signaled connection terminated again, for example by hanging up a telephone handset. For such virtual ver No ties are defined in ITU-T Recommendation I.610 speaking monitoring procedure proposed as per manent virtual connection. On the one hand, signali based virtual connections in terms of reliability on the other hand is the effort for setting up surveillance lines at the beginning of a signaled virtual connection relatively high and is often not appropriate Relationship to the connection duration or to the effort for Establish a new connection between the same part if such a signaled connection is un should be broken. Should be monitoring as before described with permanent virtual connections, are still wanted for a signaled connection, the participant or the operator of the communication system stems either wait to see what physical transmission stretch the communication system when building the virtual Connection chooses, or the options of communicati onsystems, resulting in ineffective management can result in the switching of connections.

It is known to mediate in an ATM communication system to provide facilities, of which communication ver bonds mediated or chains of physical transmissions routes for the respective communication connections can be set. Mediation is particularly well known  facilities on a central switching computer have, each of a plurality of peripheral modules controls. However, switching centers are also known, where the control function of the peripheral modules taken over by itself or from an external computer becomes.

For example, non-switching physical overvoltages load paths with an interface in one cut the LIC (Line Interface Card) module. Of the LIC are incoming ATM cells via a first multiplexer assembly AMX (ATM Multiplexing Unit), a switching matrix construction group ASN (ATM Switching Network) and a second multiple xer module AMX to an output interface on a ner output-side, second interface module LIC forwarded. When operating these peripheral modules Hardware errors and software errors occur that lead to the Ab break a virtual communication link. Genes rell is based on the Bellcore specification GR-1248-Core Issue 2, chap. 6.1.2. (September 1995 edition) demanded that at an interruption of a virtual connection within 500 ms after detection of the interruption an error signal in the virtual connection must be fed. As a mistake signals are the AIS (Alarm Indi cation signal) in the forward direction of the virtual connection as well as the RDI (Remote Defect Indication) in the reverse direction known of the virtual connection.

If one or more peripheral modules fail a switching center with a central control computer type described above, it is known that the Vorlie to the associated central tax computer is reported. The control computer then determines the affected virtual connection or the affected vir connections and notifies the associated be affected interface modules LIC. The LIC feed on the message from the control computer indicates the required signals  AlS and RDI in the virtual connection. After this ver could drive the requirement mentioned above, the or the error signals within 500 ms after detection of the Feed errors, are not adhered to.

The object of the present invention is a method of Specify the type mentioned above, which makes it possible to target Error within a communi- cation exchange determination system and in the shortest possible time after detection of the error, an error signal in a com communication link. A further task of the The invention is a switching device for switching Communication connections of a communication system stems of the type mentioned at the beginning which indicate the fast Fault detection and feeding of the fault signal allowed.

The tasks are carried out using a procedure with the characteristics of Claim 1 or by a switching device with the Features of claim 9 solved. Further training is against state of the respective dependent claims.

On the procedural side is within the switching facility of the communication system at least one monitoring route set up, at the beginning of which there was no communication cation signals monitoring signals and fed in at the end the monitoring route can be coupled out again. Under Monitoring route becomes a physical or virtual Transmission path for the transmission of communication signals len understood. The monitoring route can be part of a or multiple communication links. This commun cations connections can not only permanent virtual Connections, but also signaled subscriber bindings, intrinsic connections for the transfer of Or ganization information and / or signaled permanent virtual connections (SPVC) that the operator or user of the communication system in a particularly simple manner aimed and at least partially from the communication system  wise how signaled connections are handled. The Surveillance route is not of the type specified to it closed or connectable communication connections dependent. Rather, it is also possible, for example around the Switching device to check its functionality fen, the monitoring route without connected communication connections or only when communication is not activated to operate connections, so that in any case at the beginning no communication signals arrive on the monitoring link fen. Therefore, at least one over the monitoring route Monitoring signal fed. Meets the monitoring signal at the end of the surveillance route, at least the Fä ability of the monitoring path to transmit signals.

Communication signals are understood to be any signals those who can arrive at the beginning of the surveillance route. For example, these are user signals that by users of the communication system via a communicati on connection, or for organizational information mation between separated components of the Communication system is transmitted. Under a mediated internal monitoring route or one within one Switching device of the communication system Monitoring route is understood to be a monitoring route that extend to the limits of the switching facility can be or only via other sections of the exchange direction with interfaces to external transmission links connected is.

With the monitoring method according to the invention, errors can be Any type and cause can be determined, which too no signals at the end of the monitoring lead route. In the absence of any signals understood that no signal ended up in its expected form the surveillance route arrives. This includes the case a that, for example, only garbled signals arrive or signals that are no longer recognizable by type and format  are, e.g. B. ATM cells with damaged cell head. A white Another example are hardware errors that lead to an interruption of the monitoring route.

In response to the finding of an intermediary For example, an error diagnosis is triggered and after locating a hardware failure, re operating the redundant unit instead of the faulty unit taken. This happens e.g. B. within a few milliseconds Customers. Cause of a connection failure can also Software failure.

The monitoring method according to the invention can also be the same in time with the one known from ITU-T Recommendation I.610 Procedures are carried out. For example, on one permanent virtual connection in a known manner set up the first surveillance route on a first Switching device of the communication system has started and the second, from the first mediator Switching device remote switching ends. Furthermore, in the example there is a second one according to the invention Monitoring route within the first switching facility tion set up. About the monitoring according to the invention route are u. a. also signals of permanent virtual Connection transferable. It forms the inventive Monitoring route a section of the previously known Surveillance route. Now meets at the beginning of the known Monitoring route via the permanent virtual connection no communication signal, are over the known Monitoring section transmit monitoring signals. This go through u. a. also the monitoring according to the invention stretch so that communication signals are transmitted over it the. Only in the event of a failure or triggering the permanent vir communication link, or after a deactivation ren of the known monitoring route, it can happen that no commu over the monitoring route according to the invention nication signal is transmitted. In this case, on  catch at least the surveillance route according to the invention Monitoring signal fed.

In contrast to that in ITU-T Recommendation I.610 be written prior art, it is possible in particular by monitoring the monitoring route not just one monitor permanent virtual connection, but at least along the surveillance section all of the over communication links using the security route watch. The establishment of the surveillance route as active Monitoring route for all communications running through them tion connections is preferably automatic, esp especially when establishing the individual communication connections.

With further training there is for every active communication connection that runs over the monitoring link when switched off remain any signals of the respective communication binding at the beginning of the monitoring link specific monitoring signal. So that can connection-specific errors on the monitoring link be known, of which, for example, the other communicati connections are not affected, so that only one Communication link has failed. It can be are hardware and / or software errors.

Preferably at least one is present bidirectional communication link to the inventor appropriate surveillance line is connected in the Ge opposite direction, d. H. between the end point of the surveillance line and the starting point of the monitoring line if monitoring is carried out in the manner according to the invention leads.

In a preferred embodiment of the invention Procedures are the internal monitoring signals on a first line interface, between a in the direction of the signal in front of the switching device  ordered or arrangable external route of a communica tion line and the switching facility, fed. Alternatively or in addition, the internal ones Monitoring signals at a second line interface, between the switching device and one in signal run arranged behind the switching center or external line of a communication line that can be arranged, uncoupled. The switching device can thus up to monitored at their external border or towards their external borders become. In one variant, the monitoring signals are on another peripheral assembly, e.g. B. a switching matrix construction group, fed and / or decoupled. Especially before A configuration is added in which all mediation internal connection sections of communication connections conditions on line interfaces to external connections cut ends and / or begin and transmit the signals, in each case at least one internal monitoring link is operated. In this way, all active com communication links internal sections be monitored. It is therefore not necessary that the operator or a user of the communication system Monitoring routes expressly when establishing a connection requests or sets up. The establishment of each Monitoring route is preferably done automatically the communication system.

It is known to perform time interval measurements in order to ver determine fees dependent on the duration of the commitment. With a Wei Training of the method according to the invention is at the end any signals remain at the end of the internal switch Monitoring route such a time interval measurement ge stops. An associated counter is preferably immediate on or on a peripheral module of the exchange direction provided at the end of the surveillance route is ordered. An aftercare in the calculation of fees, to subsequently determine downtimes, ent fall.  

In a preferred further development, a monitoring system is used signal fed in if specified within a period of time Length at the beginning of the monitoring route no communication signal has arrived. In particular, the feed of a monitoring signal repeated when in a no communica for a further period of the specified length tion signal has arrived. This ensures that at the latest at the end of a period of the previous length a communication signal or monitoring signal is given to the monitoring route. Accordingly will indicate the presence of an error within the mediator processing facility closed if in a period before given length no communication signal or monitoring signal has arrived at the end of the monitoring route. The predefined length for error detection is either on set a significantly larger value than the specified one Length for the feeding of monitoring signals at the beginning the surveillance route, or it is about the same value set, but a mostly negligible small Response and execution time for the feeding of over monitoring signals at the beginning of the monitoring section must be viewed.

On the device side, a switching device of a Communication system, in particular an ATM communication systems, which is characterized in that the supply unit and the decoupling unit on one internal monitoring route of a common Communication connection are arranged, the feed unit at the beginning and the decoupling unit at the end the surveillance route. Here is the decoupling designed in such a way that it can be Monitoring signals fed in are recognized and decoupled. From the above description of the Ver driving and its training removable device  Features are for the switching device according to the invention tion or their further developments essential to the invention.

In particular, in the case of further training, mediation device the supply unit on a first line Interface arranged at the first external connection portion of a communication link to the in-Si subsequent upstream internal monitoring Chungsstrecke is connectable, and / or is the decoupling arranged on a second line interface net, on which the internal monitoring route a second external one following in signal direction Connection section of a communication link is closable.

The invention will now be described in more detail using exemplary embodiments. However, it is not limited to these exemplary embodiments. In the description of the exemplary embodiments, reference is made to the accompanying drawing. The only figure in the drawing, which is designated by FIG. 1, shows:

a monitoring route within an exchange device connected to external sections of a signali based subscriber connection is connected.

In Fig. 1, peripheral modules of a switching device 1 at a network node of an ATM (Asynchronous Transfer Mode) communication system are shown schematically. A large number of transmission paths for transmitting communication signals to and from the switching device 1 can be connected to the switching device 1 on the input and output sides. For the sake of clarity, only the input-side external transmission link 9 and the output-side external transmission link 10 are shown, each of which is a segment of an active signaled subscriber connection. The input-side external transmission path 9 ends at an interface module LIC (Line Interface Card) 2 in the switching device 1 . From there, the active signaled subscriber connection is continued via two, redundant, transmission-internal transmission levels 7 , 8 to a second interface module LIC, on which the output-side external transmission link 10 begins.

Apart from their start and end points at the first LIC 2 and at the second LIC 3, the first transmission level 7 and the second transmission level 8 have no common connection, via which communication signals of the signaled subscriber connection could be transmitted. The first transmission level 7 and the second transmission level 8 each have peripheral modules of the switching device 1 that are connected to one another in the signal running direction. Seen from the first LIC 2 , the redundant copy of a communication signal to be transmitted, which is supplied to the first 7 and second 8 transmission levels, first reaches the first multiplexer module AMX (ATM multipexing unit) 4 . From there, the communication signals are forwarded to a switching matrix module ASN (ATM switching network) 6 and coupled to an output-side connection of the ASN 6 to a second multiple module AMX 5 . The redundant copies of the communication signal are merged again by the second AMX 5 by being passed to the common second LIC 3 .

The above description applies to the error-free or undisturbed operating state of the monitoring link between the first LIC 2 and the second LIC 3 . In operation, however, it can happen that one or both transmission levels 7 , 8 fail. If only one of the transmission levels 7 , 8 fails, the transmission path between the first LIC 2 and the second LIC 3 is still fully functional, because it is sufficient if one copy of the two redundant communication signals arrives at the second LIC 3 . Furthermore, the first LIC 2 and the second LIC 3 themselves may be disturbed. Under circumstances, this leads to the fact that only one copy or no copy of a communication signal to be transmitted is given to the transmission levels 7 , 8 . In addition, it is possible that another component of the switching device 1 , for example a central switching computer (not shown), is faulty, so that the transmission of communication signals via communication link between the most LIC 2 and the second LIC 3 is disturbed. In particular, the transmission of connection data from the central switching computer to one of the LIC 2 , 3 can be disturbed. In general, software errors and hardware errors can be considered as the cause of the fault in the transmission link.

In order to monitor the transmission path between the first LIC 2 and the second LIC 3 , the first LIC 2 has a supply unit to monitor signals in the absence of communication signals which could arrive at the first LIC 2 via the external transmission path 9 on the output side to send to the second LIC 3 . If communication signals remain in a period of preferably 500 ms in length from the output-side external transmission link 9 , the first LIC 2 feeds an ATM cell into the communication link which is associated with the ATM cell type OAM (Operation, Administration, Maintenance) . Specifically, it is an iCC cell (internal continuity check cell), the cell head of which is given a special identifier. If communication signals or ATM cells remain from the external transmission path 9 for a further 500 ms, the first LIC 2 repeats the transmission of an iCC cell. As with other communication cells that arrive from the external transmission line 9 , two copies of the iCC cell are made, one of which is given to the transmission level 7 and the second transmission level 8 .

The second LIC 3 has a decoupling unit that it knows the iCC cells based on the special identifier in the cell header and decouples from the communication link or from the monitoring path between the first LIC 2 and the second LIC 3 . In a variant of the exemplary embodiment, the second LIC 3 either has two decoupling units, one of which is assigned to the first transmission level 7 and the second transmission level 8 , or it has a decoupling unit that recognizes which of the transmission levels 7 , 8 is an incoming one Communication cell arrives at the second LIC 3 . In particular, the latter can be made possible in that the redundant copies of communication cells sent by the LIC 2 are provided with different identifiers in the cell header. Preferably, however, the only decoupling unit or the two decoupling units of the second LIC 3 recognizes the transmission level 7 , 8 on the basis of the path via which the respective ATM cell arrives at the second LIC 2 . Different cell header IDs are then superfluous. In the variants of the exemplary embodiments, it is possible to determine transmission errors only in one of the two redundant transmission levels 7 , 8 and, for example, to trigger a correction of errors if the transmission of communication signals of the signaled subscriber connection by the other transmission level 7 , 8 functions without errors.

In a variant of the operating Ver shown in FIG. 1 determining device 1 is one of the transmission planes 7, 8 as redundant spare transmission level in the event of a malfunction. If, for example, the transmission level 7 is active, signals are transmitted via this transmission level. The transmission level 7 is part of the monitoring path analogous to the above description. If any signals fail due to a failure or error in the transmission level 7 at the end of the monitoring path, the system switches to the redundant transmission level 8 and operation can continue, usually without noticeable interruption. The transmission level 8 becomes part of the monitoring path, so that the monitoring function is also retained.

In the exemplary embodiment described first, the two copies of a communication signal that are transmitted via the different transmission levels 7 , 8 are not differentiated. With this configuration, the following errors can be detected, for example:

• - Hardware errors in the first LIC 2 and / or the second LIC 3 , wherein, for example, the entire LIC 2 , 3 has failed or only the interfaces belonging to the monitored or the monitored communication connections have failed.
• - Software error of one of the LIC 2 , 3 or both LIC 2 , 3 , which lead to the interruption of the communication connections that use the monitoring section as a section for the transmission of their communication signals.
• - Hardware double errors from redundant peripheral modules, both of which correspond to one another in terms of their interconnection and function, corresponding modules 4 , 5 , 6 of the transmission levels 7 , 8 are faulty or faulty.
• - Hardware cross failures of a peripheral group of the first transmission level 7 and the second transmission level 8 , the two faulty construction groups 4 , 5 , 6 are not the mutually redundant modules 4 , 5 , 6 . For example, a cross failure of the first AMX 4 of the first transmission level 7 and the second AMX of the second transmission level 8 or a cross failure of the ASM of the first transmission level 7 and the second AMX 5 of the second transmission level 8 can be determined.

In general, any errors that can lead to an interruption or failure of the signal transmission via both redundant transmission levels 7 , 8 can be determined with this configuration.

The second LIC 3 preferably has a TM unit (traffic measurement unit) which is used to measure the connection duration of one or more communication connections leading via the second LIC 3 . When establishing a connection, the TM unit receives a start pulse so that a corresponding connection duration measurement begins or a corresponding one. appropriate connection start time is recorded. If there are no communication signals of the communication connection or if there are no ATM cells associated with the communication connection for more than 500 ms at the LIC 3 , the TM unit receives from the decoupling unit or from another, intermediate unit of the second LIC 3 a stop pulse so that the time measurement is ended or the current time is recorded as the connection end time. Both ways of measuring the connection duration are understood under the term time interval measurement.

Receives the second LIC 3 after a failure of the transmission link between the first LIC 2 and the second LIC 3 again an ATM cell that is assigned to the monitored, signaled subscriber connection, for example, the transmission of AlS started after the detection of the error (Alarm Indication Signal) cells stopped in the forward direction of the subscriber connection and in the case of the connection duration measurement, a pulse is given to resume the time interval measurement.

Especially with peripheral modules that are able to to independently maintain a communication link, serves the internal monitoring of the exchange preferably for this purpose, only defects in peripheral construction groups along the surveillance route and their connection among themselves. When locating Feh This offers learners advantages in terms of quick mistakes Learning detection and correction.  

In bi-directional links is preferably in the position shown in Fig. 1 switching equipment 1 from both the LIC 2 to the LIC 3, as well as in the reverse direction from the LIC 3 to the LIC 2 is directed and operated in each case is a monitoring section. Both LIC 2 , 3 are therefore both a supply and decoupling unit for monitoring signals.

As already mentioned, the invention is not based on the previously described embodiments limited. So can too no redundant modules in the switching center to be available. For example, AIS cells are then switched off any signals stay that way at the end of the surveillance route fed on. Another hardware configuration points a bus structure on which the individual peripheral modules pen the switching device are connected. In this Case checks the respective one when a signal arrives Construction group, whether the signal, especially the ATM cell, for them is determined. Here, too, is between two modules half of the switching device at least one monitoring route set up and operated to at least one commu monitoring connection.

By monitoring internal connection monitoring Routes can failures or errors in the mediation direction can be determined reliably and quickly and it can have an error signal with practically no time delay for example an AlS cell. Furthermore it is possible without an otherwise usual after-treatment, determine the connection duration precisely.

Claims (11)

1. A method for determining errors in a communication system, in particular an ATM (Asynchronous Transfer Mode) communication system, with monitoring signals being fed in at the beginning of at least one monitoring section ( 7 , 8 ) of the communication system in the absence of communication signals and at the end of the monitoring section ( 7 , 8 ) are decoupled again, characterized in that the monitoring path ( 7 , 8 ) lies within a switching device ( 1 ) of the communication system and that if there are no signals at the end of the monitoring path ( 7 , 8 ) for the presence of an error is closed within half the switching device ( 1 ). 2. The method according to claim 1, characterized in that the internal monitoring signals at a he most line interface ( 2 ), between an in signal direction in front of the switching device ( 1 ) arranged or can be arranged external route ( 9 ) of a communication line and the switching device ( 1 ), who fed the. 3. The method according to claim 1 or 2, characterized in that the internal monitoring signals at a second line interface ( 3 ), between the switching device ( 1 ) and one in the signal direction behind the switching device ( 1 ) arranged or arranged external route ( 10 ) one Communication line, be decoupled. 4. The method according to claim 3, characterized in that in the absence of any signals at the end of the mediation internal monitoring route ( 7 , 8 ) a time interval measurement for determining connection duration-dependent fees is stopped. 5. The method according to any one of claims 1 to 4, characterized in that a monitoring signal is fed in if no communication signal has arrived in a period of a predetermined length at the beginning of the monitoring route ( 7 , 8 ). 6. The method according to claim 5, characterized, that in each case the feeding of a monitoring signal again is fetched if in a further period the specified Length no communication signal has arrived. 7. The method according to any one of claims 1 to 6, characterized in that on all internal connection sections of communication connections that start at line interfaces to external connection sections ( 9 , 10 ) and / or end and transmit the signals, at least one ver internal monitoring route ( 7 , 8 ) is operated. 8. The method according to any one of claims 1 to 7, characterized, that the surveillance route is part of a signaled commu nikationsverbindung and / or part of a signaled perma nent communication link. 9. Switching device ( 1 ) for switching communication connections of a communication system, in particular an ATM communication system, with

• 1. a feed unit ( 2 ) to feed monitoring signals into the communication link in the absence of communication signals via an active communication link, and
• 2. a decoupling unit ( 3 ) to decouple monitoring signals from an active communication link and to trigger an error message if any signals are absent,

characterized in that the infeed unit ( 2 ) and the outcoupling unit ( 3 ) are arranged on a common monitoring link ( 7 , 8 ) of a common communication link, the infeed unit ( 2 ) at the beginning and the outcoupling unit ( 3 ) at the end of the monitoring link ( 7 , 8 ) lie gene, and that the decoupling unit ( 3 ) is designed to detect and decouple monitoring signals fed in by the infeed unit ( 2 ). 10. Switching device according to claim 9, characterized in that the feed unit ( 2 ) is arranged on a first line interface, at which a first external Ver connecting section ( 9 ) to the following in the signaling direction subsequent switching internal monitoring route ( 7 , 8 ) can be closed . 11. Switching device according to claim 9 or 10, characterized in that the decoupling unit ( 3 ) is arranged on a second line interface, on which the internal monitoring path ( 7 , 8 ) to a subsequent in the signal direction second external connection section ( 10 ) can be closed .