DE102011013083A1 - Method for operation of redundant network, involves implementing measuring routine without interruption of data connection, implementing routine with existence of interruption of data connection and determining result - Google Patents

Abstract

The method involves defining two network infrastructure apparatuses e.g. switches, routers and hubs, as a transmitter and a receiver, respectively. An interruption of a data connection is defined between the infrastructure apparatuses, and a measuring routine is defined. The definitions are configured according to the apparatuses, and the routine is implemented without the interruption of data connection and a result is determined. The routine is implemented with existence of the interruption of data connection and another result is determined. The results are compared with each other.

Description

The invention relates to a method for operating a redundant network (network with redundant topology) according to the features of the preamble of claim 1.

In networks with redundant topology, which is monitored via a redundancy protocol, it should be checked during commissioning and also at regular service intervals whether network parameters such as switching times, delay, jitter, etc. are within the acceptable range.

For this purpose, some typical measuring methods and measuring instruments are already widespread, with which, however, the topology must be connected from the outside. For the plant operator, this means that additional, usually expensive, equipment must be procured, made available and operated for the measurement. In addition, the system itself must be physically intervened in order to be able to carry out measurements (connection of the measuring devices, link interruption).

It would therefore bring a significant improvement for the plant operator, if the possibility to carry out these measurements would already be included in the infrastructure devices of the network itself and this could also be carried out via a remote access. Also, it is not always possible to place the measuring devices at the desired point in the topology.

• 1) Datensender
• 2) Datenempfänger
• 3) Datenreflektor
• 4) Linkunterbrecher

For a switching time measurement in a network topology essentially the following system components are necessary:

• 1) Data transmitter
• 2) Data receiver
• 3) Data Reflector
• 4) Link breaker

These devices, which are usually to be mounted externally for each measuring cycle, should be stored permanently in the embedded software and possibly in the hardware of the infrastructure devices themselves, using the new procedure. An implementation, for example, in an Ethernet switch is completely possible in software.

A measurement scenario should then be configured via a central network management station (NMS) and the measurement cycle also started via NMS and the result also evaluated. This allows the network operator from his central network management station, even over a long distance to perform these measurements without having to go to the plant and physically intervene there.

The measuring methods that can be implemented with this method (eg packet loss, delay, jitter, performance) over one-way or two-way communication paths (with reflector) on layer 2 or layer 3 are prior art and will not be considered in detail here.

The invention is therefore based on the object to provide an improved method for operating a redundant network with a predetermined topology, with the network parameters without additional effort, preferably without additional hardware overhead, and to check during operation of the installed network.

This object is solved by the features of claim 1.

• • ein Netzwerkinfrastrukturgerät als Sender definiert wird,
• • ein Netzwerkinfrastrukturgerät als Empfänger definiert wird,
• • dass zwischen zwei Netzwerkinfrastrukturgeräten eine Unterbrechung der Datenverbindung definiert wird,
• • eine Messroutine definiert wird,
• • die Netzwerkinfrastrukturgeräte entsprechend der Definitionen konfiguriert werden,
• • die Messroutine zuerst ohne eine Unterbrechung der Datenverbindung durchgeführt und ein erstes Ergebnis ermittelt wird,
• • die Messroutine danach bei Vorhandensein der Unterbrechung der Datenverbindung durchgeführt und ein weiteres Ergebnis ermittelt wird.

According to the invention, it is provided that

• • a network infrastructure device is defined as a sender,
• • a network infrastructure device is defined as the recipient,
• That an interruption of the data connection is defined between two network infrastructure devices,
• A measuring routine is defined,
• • the network infrastructure devices are configured according to the definitions,
• The measuring routine is first performed without an interruption of the data connection and a first result is determined,
• The measuring routine is then carried out in the presence of the interruption of the data connection and a further result is determined.

As a result, the measurement of the network parameters to be measured during operation under realistic conditions without changes in the network or without intervention in the system whose sensors, actuators and the like are controlled via the network is advantageously possible.

Further possibilities or advantages of the method:

• 1) Measurement during operation under realistic conditions without changes to the system.
• 2) Flexible configuration of the measurement scenario through reconfiguration in software possible: Interrupter, transmitter, receiver or reflector can be placed at any different points of the topology (or concentrated in a device), if the existing devices support the process.
• 3) The measurement result can be output as a pass / fail value or alternatively in absolute values from the evaluation unit in the receiver or the requesting NMS.
• 4) In the case of increased demands on the measuring accuracy, the transmitter and receiver can also be realized in hardware (eg FPGA, which supports the CPU).
• 5) With increased demands on the measurement accuracy, a time synchronization (eg. IEEE 1588 ) between transmitter and receiver.
• 6) Statistical data collection by automated determination of a large number of measured values, even at different measuring points and over long periods possible without user intervention except in the initial configuration.

In a development of the invention, it is provided that the two determined results, after which the measuring routine was first performed without an interruption and then in the presence of the interruption, are compared with one another. From this it is possible to draw conclusions for the operator of the network as to whether the components of the network work faultless or faulty.

In a development of the invention, it is provided that the comparison result is stored and / or displayed. This makes it possible for the determined comparison result (eg the determined results lie in a permissible "green" area or in an impermissible "red" area) to be displayed directly on the network infrastructure device or a connected network management station, which provides the advantage in that if the comparison result is in an inadmissible range, the operator of the network can react directly to this error. If this is not necessary or is currently not possible, the comparison result can be saved and retrieved at a later date and displayed and responded accordingly. Both variants or the combination of these two individual variants has the advantage that in any case, it is possible to react directly or delayed to errors within the network without disturbing the ongoing operation of the system, which is controlled or regulated via the network ,

As already explained above, the two determined results of the measuring routines to be performed and / or the comparison result can be displayed on a network infrastructure device and / or on a network management station connected to the network. The representation on one of the network infrastructure devices within the topology of the network has the advantage that an error can be detected directly on site, which can also be directly reacted to (eg by exchanging the affected network infrastructure device). The presentation of the two results obtained and / or the comparison result on the network management station connected to the network has the advantage that the operator (administrator) of the network does not have to be on site where the network is installed. This is because the network management station can access the topology of the network far away via corresponding data connections (wired and / or wireless) and, if necessary, respond to a fault by appropriate interventions in the software routines of the individual network infrastructure devices.

In a development of the invention, it is provided that the measuring routine is stored in a memory unit, in particular an FPGA (Field Programmable Gate Array), of each network infrastructure device. This has the advantage that the software for the measuring routine is stored in an extra part of the network infrastructure device in order not to influence the otherwise available storage space and the performance of the network infrastructure device.

Instead, it is also conceivable that the measuring routine is contained in the central control unit of each network infrastructure device. This is useful if the central control unit of a network infrastructure device has sufficient storage space and performance to execute the measurement routines in the control unit of the network infrastructure device.

In the following the invention is illustrated by the figures and further explained.

In the 1 to 4 are the functional components, namely a transmitter, a receiver, a reflector and a breaker shown. These are known network infrastructure devices, such. As switches, routers, hubs, or the like. The functional components, as used in the 1 to 4 are represented, are also consistently a normal Manage Switch hardware as pure software functionality feasible. If the performance requirement is high, the functionalities as illustrated in the figures are also conceivable through implementation with hardware support (eg an FPGA).

The network infrastructure devices have in a conventional manner interfaces, such as Internet ports, wherein the switch is controlled by a central control unit CPU. The measuring routines to be described are either stored in an additional memory unit (such as the FPGA) or may be integrated in the central control unit CPU with the omission of the additional memory unit.

The in 1 illustrated transmitter includes a configurable routine in software for sending data packets, possibly with a time stamp and / or a sequence number.

The in 2 The receiver shown includes a configurable routine in software for receiving and evaluating as well as preparing the measurement results.

The in 3 The illustrated reflector includes a configurable routine in software for receiving and reflecting back packets at the transmitter according to FIG 1 ,

4 Figure 12 shows a breaker that includes a configurable routine in software for turning off the physical link to the desired port.

The in the 1 to 4 The functional components shown below are described below within a topology of a network with reference to the 5 and 6 explained in more detail.

The 5 and 6 show a known topology of a redundant network. This network accommodates various network infrastructure devices (here several switches), each of which has its own interfaces and which are interconnected via data connections and exchange data.

In the 5 and 6 the method for the redundant operation of a network for switching time measurement is shown and described below. Instead of the measuring routine for detecting the switching time, the measuring routines may also include the detection of the packet rate and / or the packet type and / or the number of interruptions and / or the jitter and / or a pass / fail criterion.

To detect the switching time in the event that a data connection between two network infrastructure devices is interrupted (eg a pulled plug or a severed cable or the like), a network infrastructure device is defined as the sender (in 5 the switch 6). It also defines which network infrastructure device should work as a receiver (in 5 the switch 2). In addition, an interruption point (interruption of the data connection) is defined (in 5 the route X). Then the measuring routine (measuring cycle) is defined (in this case the measurement of the switching time, but this is not a restriction).

Subsequently, all network infrastructure devices within the network topology or alternatively only the network infrastructure devices to be considered in accordance with the above definitions are configured via a network infrastructure device which is used as a configurator or via the network management station.

Thereafter, the first measuring routine is started, wherein the distance X is not interrupted. After starting the measurement, as in 5 shown, the measurement packets (data packets) from the transmitter (Switch 6) via the switch 4, Switch 3 to the receiver (Switch 2) sent. After the interruption of the distance X, the measurement packages must be as in 6 shown above the switch 5, switch 4, switch 3 are transported from the transmitter (switch 6) to the receiver (switch 2). In this case, the switch 4 is also called a breaker according to 4 educated.

After the two measuring routines have been carried out (with and without interruption of the distance X), in particular the network management station reads the measured values (such as the switching time, jitter, throughput and the like) from the device with the evaluation unit (namely the receiver, here the switch 2) and processes it further if necessary (eg statistical analysis, check against fail threshold and the like). Alternatively, these calculations can also be made in the evaluation unit in the respective network infrastructure device.

The results of the two measuring routines can be stored on their own or together or the comparison result of the comparison between the result of the two measuring routines or directly displayed. It is conceivable that the individual measurement results or the comparison result, possibly graphically processed, are displayed directly on the network infrastructure device and / or the network management station in order to be able to react directly to it. Depending on the nature of the measurement results, it is also conceivable to store them in a memory unit in the network infrastructure device and / or in a storage unit of the network management station in order to retrieve them later in time and then to decide whether or not to react to them.

• 1) Die Ausgangssituation der Topologie ist wie in 5 gezeigt.
• 2) Definieren, welcher Switch als Sender arbeitet (in 5 Switch 6).
• 3) Definieren, welcher Switch als Empfänger arbeitet (in 5 Switch 2).
• 4) Definieren der Unterbrechungsstelle (in 5 die Strecke X).
• 5) Messzyklus definieren (Paketrate, Pakettyp, Anzahl der Unterbrechungen, Pass/Fail-Kriterium).
• 6) Alle betroffenen Geräte entsprechend obiger Definiton über Management PC (NMS) konfigurieren.
• 7) Starten des Messzyklus: Nach dem Starten der Messung werden wie in 5 die Messpakete von dem Sender (Switch 6) über den Switch 4, Switch 3 zu dem Empfänger (Switch 2) gesendet. Nach der Unterbrechung der Strecke X müssen die Messpakete wie in 6 gezeigt über den Switch 5, Switch 4, Switch 3 zu dem Empfänger (Switch 2).
• 8) Auswertezyklus: das NMS liest die gemessenen Werte (z. B. Umschaltzeit, Jitter, Durchsatz) aus dem Gerät mit der Auswerteeinheit (Empfänger) aus und verarbeitet diese ggf. weiter (z. B. statistische Analyse, Prüfung gegen FAIL-Schwellwert etc.) Alternativ können diese Berechnungen auch in der Auswerteeinheit im Infrastrukturgerät erfolgen.
• 9) Ergebnisausgabe (z. B. als Pass/Fail-Aussage, Grafik etc.). Abrufbar über den Management PC (NMS) wie in 5, 6.

The method according to the invention is shown again in other words in other words:

• 1) The initial situation of the topology is as in 5 shown.
• 2) Define which switch works as a sender (in 5 Switch 6).
• 3) Define which switch works as the receiver (in 5 Switch 2).
• 4) Defining the point of interruption (in 5 the route X).
• 5) Define measurement cycle (packet rate, packet type, number of interrupts, pass / fail criterion).
• 6) Configure all affected devices according to the above definition via Management PC (NMS).
• 7) Starting the measuring cycle: After starting the measurement, as in 5 the measurement packets are sent from the transmitter (switch 6) via the switch 4, switch 3 to the receiver (switch 2). After the interruption of the distance X, the measurement packages must be as in 6 shown via the switch 5, switch 4, switch 3 to the receiver (switch 2).
• 8) Evaluation cycle: the NMS reads out the measured values (eg switching time, jitter, throughput) from the device with the evaluation unit (receiver) and, if necessary, processes these further (eg statistical analysis, check against FAIL threshold value etc.) Alternatively, these calculations can also be made in the evaluation unit in the infrastructure device.
• 9) Result output (eg as pass / fail statement, graphic etc.). Available via the Management PC (NMS) as in 5 . 6 ,

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• IEEE 1588 [0012]

Claims (8)

A method for redundantly operating a network, wherein the network has a predefinable topology within which multiple network infrastructure devices communicate with each other via data links, each network infrastructure device having at least one interface to which a data connection is connected, characterized by: defining a network infrastructure device as a sender is defined as: • a network infrastructure device is defined as the recipient, • a network connection between two network infrastructure devices is defined, • a measurement routine is defined, • the network infrastructure devices are configured according to the definitions, • the measurement routine is performed first without a data connection interruption, and a first Result is determined, • the measuring routine then performed in the presence of the interruption of the data connection and another result ermit telt. Method for the redundant operation of a network according to claim 1, characterized in that the two determined results are compared with each other. Method for the redundant operation of a network according to claim 2, characterized in that the comparison result is stored and / or displayed. Method for the redundant operation of a network according to claim 1 or 2, characterized in that the two determined results and / or the comparison result is displayed on a network infrastructure device. Method for the redundant operation of a network according to claim 1 or 2, characterized in that the two determined results and / or the comparison result is displayed on a network management station connected to the network. Method for redundantly operating a network according to one of the preceding claims, characterized in that the measuring routine determines the packet rate and / or the packet type and / or the number of interruptions and / or the jitter and / or the switching time and / or a pass / fail Includes criterion. Method for the redundant operation of a network according to one of the preceding claims, characterized in that the measuring routine is stored in a memory unit, in particular an FPGA, of each network infrastructure device. Method for the redundant operation of a network according to one of the preceding claims, characterized in that the measuring routine is contained in the central control unit of each network infrastructure device.

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