DE102024111705B4 - Method for the automatic detection and documentation of the execution of a measurement with regard to a data communication connection - Google Patents

Abstract

The invention relates to a method, in particular for the automatic detection and documentation of the execution of a measurement with respect to a data communication link (100) between a first communication endpoint (30, 41) and a second communication endpoint (43, 50), wherein the data communication link (100) runs at least via a first network element (41) of a core network (40) configured for data transmission. A measuring device (20) is connected to the first network element (41). By means of the method, information supplied by the measuring device (20), in particular about the start of a measurement operation, the ongoing measurement operation, and the end of the measurement operation with respect to the data communication link (100), can be automatically detected by the first network element (41) and transferred to a network management system (70) for documentation purposes via a data communication network (60) separate from the core network (40).

Description

The invention relates to a method, in particular for the automatic detection and documentation of the execution of a measurement with respect to a data communication link that runs between a first and a second communication endpoint.

It is known to measure the transmission characteristics of a digital communication link between two subscriber terminal equipment, which can be connected directly or via a network termination unit to a telecommunications core network, using an externally connected measuring device. Depending on the implementation, the measuring device can, for example, be connected to one of the network termination units. The core network can be, for example, an optical transport network according to the ITU-T G.709 standard. As long as a measuring device is connected, normal operation over the communication link is not possible, so that alarm notification, performance data collection, and its evaluation cannot be reliably performed. Performance data relates to defined performance characteristics of the communication link and is particularly needed to determine a performance indicator, also known as a key performance indicator (KPI), for the communication link being measured. Furthermore, to define the timing of the measurement phases, timestamps for the respective start and end of each measurement may need to be manually entered into a network management system, possibly multiple times.

From the US 2015/0104167 A1 A method for determining the properties of an optical communication path between a first and a second optical network node is known. For this purpose, a time difference between the respective first and second optical test signals, transmitted from the first optical network node at different wavelengths, is determined at the second optical network node. Furthermore, a chromatic dispersion parameter is determined in real time for each wavelength at the second optical network node.

From the US 2013/0195442 A1 A transmission device and a method for measuring the propagation delay in a transmission system, in which a frame is transmitted between a first and a second transmission device, are known. For this purpose, propagation delay measurements are performed several times to determine the time interval between the transmission of a first frame from the first to the second transmission device and the reception of a second frame that was sent from the second to the first transmission device. The propagation delay is then determined from the measurement results.

From the EP 3 179 676 B1 A delay measuring device of a communication system is known. The delay measuring device sends and receives successive frames of known frame length. The communication system includes a measuring device that serves to measure the cycle time of the object being measured by the delay measuring device.

In the US 2018/0175965 A1 This describes a control method for a network, where the method is executed by a processor of a network control device. According to the method, the time required to generate an optical path spanning multiple nodes of a network is measured. Furthermore, the optical path is set at a time that is controlled based on the measured time value.

From the US 2023/0300050 A1 A method for measuring traffic volume during path switching is known, wherein the method is executed by a first device. For this purpose, OAM (Operation Administration and Maintenance) frames are continuously sent from the first device to a second device and OAM frames are received from the second device. Based on the received OAM frames, a start and stop time for the traffic volume are determined.

In the US 2014/0314401 A1 This describes, among other things, a transmission system for selecting a path from a multitude of paths that exist between a first and a second transmission device. The first device is configured to transmit a frame to the second device via each of the paths. The second device is configured to measure a delay time for each path using a frame transmitted between the second and first devices. Based on the measured delay times, a path is selected.

The present invention is based on the objective of providing a method with which measurement phases of a data communication connection can be determined and documented more precisely and reliably.

An advantageous aspect of the invention can be seen in providing a method, in particular for the automatic detection and documentation of the execution of a measurement with respect to a data communication link existing between two communication endpoints, wherein the data communication link is at least via a first network element of a core network designed for data transmission. The process proceeds as follows. A measuring device is connected to the first network element. Using this method, information supplied by the measuring device, in particular regarding the start, ongoing, and end of a measurement operation, can be automatically detected by the first network element with respect to the data communication link and transferred to a network management system for documentation purposes via a data communication network separate from the core network.

The above-mentioned technical problem is solved by the features of claim 1.

1. a) Verbinden eines Messgeräts mit dem ersten Netzelement;
2. b) Übertragen eines ersten Signals, welches eine Startinformation enthält, die den Beginn eines Messbetriebs signalisiert, vom Messgerät zum ersten Netzelement;
3. c) Übertragen nach Beendigung des Messbetriebs eines zweiten Signals, welches eine Stoppinformation enthält, die das Ende des Messbetriebs signalisiert, vom Messgerät zum ersten Netzelement;
4. d) nach Ausführung des Schritts b) und vor Ausführung des Schritts c) wiederholtes Übertragen eines dritten Signals, welches eine Messbetriebs-Information enthält, die einen laufenden Messbetrieb hinsichtlich der Daten-Kommunikationsverbindung signalisiert, vom Messgerät zum ersten Netzelement;
5. e) Erkennen, durch das erste Netzelement, die Startinformation im ersten Signal, die Stoppinformation im zweiten Signal und die Messbetriebs-Information in jedem dritten Signal und Übertragen der empfangenen Startinformation, der empfangenen Stoppinformation und jeder der empfangenen Messbetriebs-Informationen vom ersten Netzelement zu einem Netzmanagementsystem (NMS) über ein vom Kernnetz getrenntes Datenkommunikationsnetz, wobei das Kernnetz und das vom Kernentz getrennte Datenkommunikationsnetz unterschiedliche Kommunikationsprotokolle unterstützen; und
6. f) Speichern der in Schritt e) übertragenen Informationen in dem Netzmanagementsystem zur Dokumentation der Durchführung einer Messung bezüglich der Daten-Kommunikationsverbindung.

Accordingly, a method is provided, in particular for the automatic detection and documentation of the execution of a measurement with respect to a data communication link existing between a first and a second communication endpoint, wherein the data communication link runs at least via a first network element of a core network designed for data transmission. The method comprises, for example, the following procedural steps:

1. a) Connecting a measuring device to the first network element;
2. b) Transmission of a first signal containing start information that signals the start of a measurement operation, from the measuring instrument to the first network element;
3. c) After the measurement operation has ended, a second signal containing stop information, signaling the end of the measurement operation, is transmitted from the measuring device to the first network element;
4. d) after execution of step b) and before execution of step c), repeated transmission of a third signal, which contains measurement operation information indicating an ongoing measurement operation with respect to the data communication link, from the measuring device to the first network element;
5. e) Detect, by the first network element, the start information in the first signal, the stop information in the second signal, and the measurement operation information in every third signal, and transmit the received start information, the received stop information, and each of the received measurement operation information from the first network element to a network management system (NMS) via a data communication network separate from the core network, wherein the core network and the data communication network separate from the core network support different communication protocols; and
6. f) Storing the information transferred in step e) in the network management system to document the performance of a measurement regarding the data communication link.

It should be noted that the first, second and every third signal preferably form a data frame comprising several bytes, the data frame being implemented in particular according to a predetermined communication protocol, for example according to the ITU-T G.709 standard.

It should also be noted that the measuring device can be connected directly to the first network element. In this case, the first network element can be considered the first communication endpoint, which is designed for the direct connection of at least one subscriber terminal device. A subscriber terminal device is, for example, a computer, a router, a switch, or even the measuring device itself. Alternatively, the measuring device can also be connected indirectly to the first network element, for example, via a customer-side network termination unit. In this case, the network termination unit can be considered the first communication endpoint.

According to an advantageous embodiment, the core network can be a standardized optical transport network (OTN), in particular an optical transport network according to the ITU-T G.709 standard. In this case, the first network element is an OTN network element, which can be configured, for example, as an optical OTN terminal, an OTN ADD/DROP multiplexer, an OTN cross-connector, or an OTN network termination. Such OTN network elements are known to those skilled in the art.

Communication between the measuring device and the first network element preferably takes place via a standardized communication protocol, such as the Ethernet protocol according to an IEEE 802.3 standard, an OTN protocol according to the ITU-T G.709 standard or a Fibre Channel protocol stack (FC-P).

• Unter Ansprechen auf die in Schritt b) übertragene Startinformation Erzeugen, durch das erste Netzelement, einer ersten Status-Information, die signalisiert, dass der aktuelle Betriebszustand ein Messbetrieb ist;
• unter Ansprechen auf die in Schritt c) übertragene Stoppformation Erzeugen, durch das erste Netzelement, einer zweiten Status-Information, die signalisiert, dass der Messbetrieb beendet ist und/oder die Daten-Kommunikationsverbindung sich wieder im normalen Kommunikations-Betriebszustand befindet;
• Übertragen der ersten und zweiten Status-Information vom ersten Netzelement zum Netzmanagementsystem über das vom Kernnetz getrennte Datenkommunikationsnetz; und
• Speichern der ersten und zweiten Status-Information im Netzmanagementsystem zur Dokumentation der Durchführung einer Messung bezüglich der Daten-Kommunikationsverbindung.

In order to reliably record the operational status of the data communication link, the procedure can, according to an advantageous further development, include the following additional steps:

• By responding to the start information transmitted in step b), the first network element generates an initial status information signaling that the current operating state is a measurement operation;
• By responding to the stop formation transmitted in step c), the first network element generates a second status information signaling that the measurement operation is finished and/or the data communication link is back in normal communication operating state;
• Transmission of the first and second status information from the first network element to the network management system via the data communication network, which is separate from the core network; and
• Storing the first and second status information in the network management system to document the execution of a measurement regarding the data communication connection.

In order to reliably document the status of the data communication link, preferably the first signal transmitted in step b), the second signal transmitted in step c), and every third signal transmitted in step d) can each contain information to identify the data communication link, wherein
the information for identifying the data communication link is transmitted from the first network element to the network management system, and wherein
The information for identifying the data communication connection is stored in the network management system for the documentation of the execution of a measurement regarding the data communication connection.

Optionally or additionally, at least the first signal transmitted in step b) may contain at least one piece of information relating to the measurement and/or at least one piece of information identifying the measuring instrument, wherein
at least one piece of information relating to the measurement and/or at least one piece of information identifying the measuring device is transmitted from the first network element to the network management system, and wherein
at least one piece of information relating to the measurement and/or at least one piece of information identifying the measuring device is stored in the network management system for the documentation of the execution of a measurement with regard to the data communication connection.

• Übertragen der im ersten, zweiten und in jedem dritten Signal empfangenen Informationen vom ersten Netzelement zum zweiten Netzelement über das Kernnetz und Weiterleiten dieser Informationen vom zweiten Netzelement zum Netzmanagementsystem über das vom Kernnetz getrennte Datenkommunikationsnetz; und
• Speichern der empfangenen Informationen in dem Netzmanagementsystem zur Dokumentation der Durchführung einer Messung bezüglich der Daten-Kommunikationsverbindung.

According to an advantageous embodiment, the data communication link can run at least section by section between the first network element and a second network element of the core network, the method comprising the following further steps:

• Transmission of the information received in the first, second, and every third signal from the first network element to the second network element via the core network, and forwarding of this information from the second network element to the network management system via the data communication network, which is separate from the core network; and
• Storing the received information in the network management system to document the execution of a measurement regarding the data communication link.

The second network element can also be an OTN network element, which can be configured, for example, as an optical OTN terminal, an OTN ADD/DROP multiplexer, an OTN cross-connector, or an OTN network termination. Such OTN network elements are known to those skilled in the art.

To enable decentralized documentation, the information contained in the first, second and every third signal can advantageously also be stored in the first and/or second network element.

• Übertragen, in Schritt b), in dem ersten Signal wenigstens eines Steuerbefehls, welcher für die zweite Kommunikations-Endstelle bestimmt ist, wobei der wenigstens eine Steuerbefehl Anweisungen zum Ausführen einer vorbestimmten Aktion durch die zweite Kommunikations-Endstelle enthält;
• Übertragen des wenigstens einen Steuerbefehls vom ersten Netzelement zur zweiten Kommunikations-Endstelle; und
• in Abhängigkeit von dem wenigstens einen empfangenen Steuerbefehl Ausführen der vorbestimmten Aktion durch die zweite Kommunikations-Endstelle, die auch als Kommunikations-Gegenstelle betrachtet werden kann.

To increase flexibility regarding measurement requirements, the procedure can include the following steps:

• Transmitted, in step b), in the first signal of at least one control command which is intended for the second communication terminal, wherein the at least one control command contains instructions for the execution of a predetermined action by the second communication terminal;
• Transmission of at least one control command from the first network element to the second communication endpoint; and
• Depending on the at least one control command received, the predetermined action is executed by the second communication endpoint, which can also be considered the communication counterpart.

It should be noted that the first and second communication terminals can each be configured to connect a subscriber terminal, so that in normal operation two communication terminals can communicate with each other via the data communication link.

According to an advantageous embodiment, the data communication link can run at least section by section between the first network element and a second network element of the core network, wherein the second communication endpoint is the second network element of the core network. is, and wherein the procedure comprises the following steps;
Transmission of at least one control command from the first network element to the second network element, which acts as the second communication endpoint;
Depending on the at least one control command received, the second network element executes the predetermined action;
Transmission of the control command from the first and/or second network element to the network management system via the separate data communication network; and
Storing the control command transmitted by the first and/or second network element in the network management system to document the execution of a measurement regarding the data communication link.

According to an advantageous alternative embodiment, the data communication link can run at least section by section between the first network element and a second network element of the core network, wherein the second communication endpoint is directly connected to the second network element of the core network, wherein the at least one control command is transmitted from the first network element via the second network element to the second communication endpoint, and wherein the method comprises the following steps;
Depending on the at least one control command received, the predetermined action is executed by the second communication terminal;
Transmission of the control command from the first and/or second network element to the network management system via the data communication network, which is separate from the core network; and
Storing the control command transmitted by the first and/or second network element in the network management system to document the execution of a measurement regarding the data communication link.

In this case, the second communication endpoint can be a subscriber-side network termination unit to which a subscriber terminal device can be connected.

The predetermined action may, for example, involve the formation of a test loop, in particular the formation of a software-based test loop in the second communication endpoint, in order to transmit data transferred from the measuring device via the data communication link back to the measuring device during a measurement operation.

• Ausführen, durch das Messgerät, vorbestimmter Messungen bezüglich der Daten-Kommunikationsverbindung zwischen der ersten und zweiten Kommunikations-Endstelle; und
• Bereitstellen der durch die vorbestimmten Messungen gewonnenen Messwerte zur weiteren Verwendung.

According to a beneficial further training, the procedure may include the following steps:

• To perform, by means of the measuring device, predetermined measurements regarding the data communication link between the first and second communication endpoints; and
• Providing the measured values obtained through the predetermined measurements for further use.

The predetermined measurements can be used to determine, in particular, transmission characteristics of the data communication link, such as the maximum data rate, the transmission duration and/or the number of lost or incorrectly transmitted data.

• 1 ein beispielhaftes, die Erfindung verwirklichendes Kommunikationssystem, in dem die Daten-Kommunikationsverbindung zwischen zwei, jeweils als Netzabschlusseinheit ausgebildeten Kommunikations-Endstellen verläuft,
• 2 ein weiteres beispielhaftes, die Erfindung verwirklichendes Kommunikationssystem, in dem die Daten-Kommunikationsverbindung zwischen zwei jeweils als Kommunikations-Endstelle fungierenden OTN-Netzelementen verläuft,
• 3 ein beispielhaftes, die Erfindung verwirklichendes Kommunikationssystem, in dem die Daten-Kommunikationsverbindung zwischen zwei jeweils als Netzabschlusseinheit ausgebildeten Kommunikations-Endstellen, die an einem gemeinsamen OTN-Netzelement angeschlossen sind, verläuft, und
• 4 ein Ablaufdiagramm eines beispielhaften Messbetriebs.

The present invention is explained in more detail below with reference to exemplary embodiments in conjunction with the accompanying drawings. These show:

• 1 an exemplary communication system realizing the invention, in which the data communication link runs between two communication endpoints, each designed as a network termination unit,
• 2 another exemplary communication system realizing the invention, in which the data communication link runs between two OTN network elements, each acting as a communication endpoint,
• 3 an exemplary communication system realizing the invention, in which the data communication link runs between two communication endpoints, each designed as a network termination unit and connected to a common OTN network element, and
• 4 A flowchart of an exemplary measurement operation.

1 Figure 10 shows an exemplary communication system comprising a core network 40, which in this example is configured as an optical transport network (OTN) according to the ITU-T G.709 standard. The optical transport network 40 is a telecommunications network used to transmit user data via a transport service. It should be noted that several individual optical transport networks can also be connected to form a common core network. According to the ITU-T G.709 standard, user data is transmitted in data frames, the so-called optical transport units (OTUs), preferably at transmission rates of 2.66 Gbit/s, 10.7/11.1 Gbit/s, 112 Gbit/s, or multiples of 112 Gbit/s. Dense Wavelength Division Multiplexing (DWDM) is particularly well-suited as the optical multiplexing technique.

The optical transport network 40 comprises several optical network elements, hereinafter also referred to as OTN network elements, which can be interconnected via optical fiber links. For the sake of clarity, only four optical network elements 41-44 and the fiber optic links 80-84 connecting them are shown. The OTN network elements 41-44 of the optical transport network 40 are preferably configured as an OTN terminal, an OTN ADD/DROP multiplexer, an OTN cross-connector, or an OTN network termination. Such OTN network elements are known to those skilled in the art and are therefore not described in more detail here.

To handle the aforementioned high transmission rates, each of the fiber optic links 80-84 preferably has two separate optical fibers to enable bidirectional data transmission. Each of the two optical fibers is used for a different transmission direction.

Furthermore, the communication system 10 comprises at least two communication endpoints. In the exemplary embodiment, only the two communication endpoints 30 and 50 are shown. The communication endpoints 30 and 50 are, for example, designed as network termination units, which are preferably implemented on the customer side and in which the 1 In the depicted operating scenario, the endpoints or communication endpoints of a schematically represented data communication link 100 function as endpoints or communication terminals. According to an exemplary implementation, the two communication terminals 30 and 50 can each be configured as an optical network unit (OTN-NT of Optical Transport Network-Network Termination). If the two network termination units 30 and 50 are not implemented or are not used, then the two OTN network elements 41 and 43 form, as shown in 2 to see the communication endpoints of a data communication link 101. It is also conceivable that in the embodiment according to 1 Only one of the two network termination devices 30 and 50 is implemented. In this case, either the OTN network element 41 and the network termination device 50, or the network termination unit 30 and the OTN network element 43 form the two communication endpoints of the data communication link 100.

As in 1 As shown, the communication endpoint 30 is, for example, directly connected to the optical network element 41 of the optical transport network 40 via a fiber optic cable 90. In order to exchange data between the communication endpoint 30 and the optical network element 41 in a predetermined manner, the communication endpoint 30 and the optical network element 41 each have a communication interface 31 or 41.1, respectively, which implement a standardized communication protocol, for example, the communication protocol according to the ITU-T G.709 standard.

Similarly, the communication terminal 50 is directly connected to the optical network element 43 of the optical transport network 40 via an optical fiber 91. To enable data exchange between the communication terminal 50 and the optical network element 43 in a predetermined manner, the communication terminal 50 and the optical network element 43 each have a communication interface 51 and 43.1, respectively, which implement a standardized communication protocol, for example, the communication protocol according to the ITU-T G.709 standard.

Each of the communication endpoints 30 and 50, configured as network termination units, has a communication interface 32 or 52, to which a subscriber terminal device, such as a coupling element, a router, a switch, a server, or a measuring device 20, is connected. If a router/switch is used, at least one computer can be connected to the router/switch in a manner known per se. 1 As shown, a subscriber terminal equipment 130 can be connected to the communication interface 52 of the network termination device 50.

How 1 As further shown, for measurement purposes a measuring device 20 can be connected to the optical network element 41 via the network termination unit 30, which acts as a communication endpoint. For this purpose, the measuring device 20 can be connected directly to the communication interface 32 of the network termination unit 30 by means of a communication interface 21. As alternatively shown in 2 As shown, if the network termination unit 30 is missing, the measuring device 20 can also be connected directly to the communication interface 41.1 of the optical network element 41, which acts as a communication endpoint, via the communication interface 21.

How 1 As further exemplified, the optical network elements 41-44 each have a communication interface 41.2, 42.1, 43.2, and 44.1, respectively, by means of which they are connected via a separate data communication network 60 to a network management system (NMS) 70 and can communicate according to a predefined communication protocol. The network management system 70 and the communication interfaces 41.2, 42.1, 43.2, and 44.1 implement, for example, a standard communication protocol such as... For example, an Ethernet protocol according to an IEEE 802.3 standard or the Internet Protocol. The network management system 70 is configured to monitor and control the optical transport network 40, its optical network elements 41-44, and optionally also the network termination units 30 and 50. Control or monitoring information intended for the network termination units 30 and 50 is transmitted by the network management system 70 via the data communication network 60 to the OTN network element 41 or 43, and from there via appropriate in-band channels, which are configured, for example, according to the communication protocol of the ITU-T G.709 standard, to the network termination unit 30 or 50. The separate data communication network 60 is preferably an isolated network secured by firewalls, which supports communication between the network management system 70 and the optical network elements 41-44 using a preferably standardized communication protocol.

2 shows an exemplary communication system 10', which differs from the one in 1 The communication system 10 shown differs in that only the two network termination devices 30 and 50 are not present. Therefore, in 2 for the matching characteristics, the reference numerals from the 1 The measuring device 20 is now directly connected to the communication interface 41.1 of the OTN network element 41. In this case, the two OTN network elements 41 and 43 each form a communication endpoint of the data communication link 101. The OTN network element 43, functioning as a communication endpoint, is configured to be directly connected to a subscriber terminal 130'. For this purpose, the subscriber terminal 130' has a correspondingly configured communication interface 131', which preferably implements the communication protocol according to the ITU-T G.709 standard.

3 shows another exemplary communication system 10'', which differs from the one in 1 The communication system 10 shown differs in that not only the network termination unit 30, but also another network termination unit 110 is directly connected to the OTN network element 41, for example via a fiber optic cable 92. For this purpose, the network termination unit 110 has a communication interface 111 and the OTN network element 41 has a further communication interface 41.3, which, for example, implement the communication protocol according to the ITU-T G.709 standard. In this case, the two network termination units 30 and 110 each form a communication endpoint of a data communication link 102, which is routed only via a single OTN network element, namely the OTN network element 41. The network termination unit 110 preferably has a communication interface 112 for connecting a subscriber terminal, for example the terminal 130.

The following describes the functionality of the [tool] as an example. 1 The communication system shown in section 10 is explained in more detail.

It should be noted here that, according to an exemplary implementation, the communication system is specifically designed to automatically detect the operating state of a data communication link, i.e., to recognize whether a data communication link between a first and a second communication endpoint—in this example, a data communication link 100 between communication endpoint 30 and communication endpoint 50, schematically represented by a dashed line—is in measurement mode or in normal transmission mode. The current state is then signaled to the network management system 70 and documented there.

Let us first assume that the network operator of the optical transport network 40 has, at the customer's request, established a permanent data communication link 100 between communication endpoint 30 and communication endpoint 50, or configured it in the network management system 70, for example, taking into account the unique address information of the two communication endpoints 30 and 50. The data communication link 100, functioning as an end-to-end connection, runs from communication endpoint 30 to optical network element 41 and then via optical network element 43 to communication endpoint 50. Depending on the configuration and implementation, the data communication link 100 can be routed via at least one further, interposed optical network element of the optical transport network 40, for example, via optical network element 42. Depending on the implementation, the communication system 10 can be trained to detect the failure of optical network elements of the optical transport network 40 and to ensure that, in the event of a failure of, for example, the optical network element 42, the data communication link 100 established between the communication endpoint 30 and the communication endpoint 50, which is also routed through the two OTN network elements, is maintained, for example, by including the optical network element 44.

Furthermore, it is now assumed that the measuring device 20 is connected to the network termination unit 30, which acts as a communication endpoint, and is connected via this unit to the optical network element 41 in order to perform a measurement regarding the data communication link 100. As already explained above by way of example, the communication endpoint 30 and the optical network element 41 each have a communication interface 31 and 41.1 respectively, which implement a standardized communication protocol, for example, the communication protocol according to the ITU-T G.709 standard.

According to an exemplary implementation, the measuring device 20 can be configured to generate predetermined binary pseudorandom sequences, for example, a pseudorandom binary sequence (PRBS) known to those skilled in the art. For example, a PRBS23 can be generated that is repeated every 8388607 bits.

• eine Information zur eindeutigen Kennzeichnung der Daten-Kommunikationsverbindung 100,
• eine Information über das erste Kommunikationsprotokoll, welches zur Kommunikation zwischen dem Messgerät 20 und der Netzabschlusseinheit 30 verwendet wird,
• eine Information über das Kommunikationsprotokoll, welches zur Kommunikation zwischen den optischen Netzelementen 41 bis 44 und dem Netzmanagementsystem 70 verwendet wird,
• eine Information über das Kommunikationsprotokoll, welches zur Kommunikation zwischen den optischen Netzelementen des optischen Transportnetzes 40 verwendet wird,
• einen Steuerbefehl, der eine Anweisung an eine Gegenstelle, im vorliegenden Beispiel an die als Kommunikations-Endstelle bzw. Gegenstelle fungierende Netzabschlusseinheit 50, zur Ausführung einer vorbestimmten Aktion enthält, wenigstens eine die Messung betreffende Information und/oder wenigstens eine das Messgerät 20 kennzeichnende Information,
• eine Zufallszahl.

Assume that the measuring device 20 generates a start signal which contains at least one start piece of information that signals the beginning of a measurement operation. The start signal can, for example, form a data frame with n bytes, where n is, for example, equal to 64. The start piece of information can be represented by a binary 1. In addition to the start piece of information, the start signal can optionally contain at least one of the following pieces of information:

• Information for the unique identification of the data communication connection 100,
• information about the first communication protocol used for communication between the measuring device 20 and the network termination unit 30,
• information about the communication protocol used for communication between the optical network elements 41 to 44 and the network management system 70,
• information about the communication protocol used for communication between the optical network elements of the optical transport network 40,
• a control command containing an instruction to a counterpart, in the present example to the network termination unit 50 acting as a communication endpoint or counterpart, to execute a predetermined action, at least one piece of information relating to the measurement and/or at least one piece of information identifying the measuring device 20,
• a random number.

The information relating to the measurement may include the minimum and/or maximum size of the data frame used, the core network 40 used, the data rate, the wavelength of light used for data transmission, and similar information. The information identifying the measuring instrument 20 may include the serial number and/or the type of measuring instrument.

According to the exemplary implementation, the start signal is transmitted as a binary pseudorandom sequence via the network termination unit 30, which acts as a communication endpoint, to the optical network element 41. The optical network element 41 is configured to recognize the information contained in the start signal and, depending on the implementation, to store it in a local storage device and forward it to the network management system 70 via the data communication network 60 for documentation purposes.

Depending on the implementation, during an ongoing measurement, for example, after the transmission of a predetermined number of binary pseudorandom sequences, another signal is repeatedly generated by the measuring device 20 and transmitted to the optical network element 41. Each subsequent signal contains measurement operation information that indicates ongoing measurement operation with respect to the data communication link 100, i.e., that the measuring device 20 is still in measurement operation. Each subsequent signal can, for example, form a data frame with n bytes, where n is, for example, equal to 16. The measurement operation information can, for example, be the random number transmitted in the first signal, which, depending on the implementation, can also identify the data communication link 100. The optical network element 41 is configured to recognize the measurement operation information contained in each subsequent signal and, depending on the implementation, to store it in a local storage device and forward it to the network management system 70 via the data communication network 60 for documentation purposes.

Assume that the measuring device 20 is configured to send a control command to the optical network element 41 in the start signal, intended for the remote station, here the network termination unit 50 acting as the communication endpoint or remote station. The control command contains an instruction to the network termination unit 50 to perform a specific action. This specific action could, for example, involve establishing a test loop.

In this case, the optical network element 41 can be configured to recognize the control command contained in the start signal and to The control command, for example, in an optical transport unit (OTE), is transmitted via the optical transport network 40 and the optical network element 43 to the network termination unit 50. At least the network termination unit 50, which functions as a communication endpoint, is configured to recognize and execute the control command contained in the received optical transport unit. This is achieved, for example, by the network termination unit 50 establishing a software-based check loop to transmit data coming from the communication endpoint 30 or the optical network element 41 back to the optical network element 41 or the communication endpoint 30. The network termination unit 50 can also be configured to generate action information describing the predetermined action to be performed by the network termination unit 50 and to transmit the control command and/or the action information via the data communication network 60 to the network management system 70. The control command and/or the action information are then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 100.

The measurement process with respect to the data communication link 100 is terminated by the measuring device 20 generating a stop signal, which contains at least one stop piece of information signaling the end of the measurement operation. The stop signal can, for example, form a data frame with n* bytes, where n is, for example, equal to 64. The stop information can be represented by a binary 0. In addition to the stop information, the stop signal can contain at least one of the other pieces of information that can also optionally be included in the start signal. According to the exemplary implementation, the stop signal is transmitted in a binary pseudorandom sequence via the communication endpoint 30 to the optical network element 41. The optical network element 41 is configured to recognize the information contained in the stop signal and, depending on the implementation, to store it in a local storage device and forward it to the network management system 70 via the data communication network 60.

In order to be able to use the data communication link 100 normally for data transmission again after the measurement process, the measuring device 20 is preferably configured to send a control command in the stop signal to the optical network element 41, which is intended for the network termination device 50 acting as the communication endpoint or counterpart. The control command contains an instruction to the network termination device 50 to perform a specific action. The specific action can, for example, involve removing a software-based test loop. In this case, the optical network element 41 can be configured to recognize the control command contained in the stop signal and to transmit the control command, for example, in an optical transport unit (OTE) via the optical transport network 40 and the OTN network element 43 to the network termination unit 50 acting as the counterpart. The network termination unit 50 is configured to recognize and execute the control command contained in the received optical transport unit by removing the previously formed software-based test loop. The network termination unit 50 can further be configured to generate action information describing the predetermined action performed by the network termination unit 50 and to transmit the control command and/or the action information via the OTN network element 43 and the data communication network 60 to the network management system 70. The control command and/or the action information are then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 100.

For the automatic documentation of the status of the data communication link 100, the information contained in the start signal, the stop signal and in each of the other signals is transmitted from the optical network element 41 to the network management system 70 via the data communication network 60 and stored there for documentation purposes regarding the data communication link 100.

Depending on the implementation, the information contained in the start signal, the stop signal, and each of the other signals can also be transmitted from the optical network element 41 to the remote device, here the optical network element 43, and from the optical network element further routed via the data communication network 60 to the network management system 70 and stored there. Preferably, both the optical network element 41 and the optical network element 43 are configured to recognize the information contained in the start signal, the stop signal, and each of the other signals and to store it at least until the measurement operation has ended.

• - unter Ansprechen auf die im Start-Signal enthaltene Startinformation eine erste Status-Information, die signalisiert, dass der aktuelle Betriebszustand der Daten-Kommunikationsverbindung 100 ein Messbetrieb ist, zu erzeugen,
• - unter Ansprechen auf die im Stopp-Signal enthaltene Stoppinformation eine zweite Status-Information, die signalisiert, dass der aktuelle Betriebszustand der Daten-Kommunikationsverbindung 100 ein normaler Kommunikationsbetrieb ist, zu erzeugen, und

die erste und zweiten Status-Information über das Datenkommunikationsnetz 60 zum Netzmanagementsystem 70 zu übertragen, wobei die erste und zweite Status-Information im Netzmanagementsystem 70 zur weiteren Verwendung, insbesondere zu Dokumentationszwecken gespeichert werden.At least the optical network element 41 is designed to

• - by responding to the start information contained in the start signal, to generate an initial status information indicating that the current operating state of the data communication link 100 is a measurement operation,
• - by responding to the stop information contained in the stop signal, to generate a second status information signaling that the current operating state of the data communication link 100 is normal communication operation, and

to transmit the first and second status information via the data communication network 60 to the network management system 70, whereby the first and second status information is stored in the network management system 70 for further use, in particular for documentation purposes.

Optionally, the optical network element 41 is configured to transmit the first and second status information via the optical transport network 40 to the optical network element 43. The first and second status information can optionally be stored in the optical network element 43 and transmitted via the data communication network 60 to the network management system 70.

The binary pseudorandom sequences generated and transmitted by the measuring device during a measurement operation, which may be transmitted back to the measuring device 20 by the remote device (here, the network termination unit 50), can be used by the measuring device 20 to measure transmission characteristics of the data communication link 100. In this way, for example, faulty data transmission and failure to meet a contractually agreed data rate can be detected.

• Die Daten-Kommunikationsverbindung 101 verläuft zwischen den beiden als Kommunikations-Endstellen fungierenden OTN-Netzelementen 41 und 43.
• Ein Start-Signal, wiederholt übertragene Signale, die einen laufenden Messbetrieb signalisieren, und ein Stopp-Signal werden vom Messgerät 20 direkt zum OTN-Netzelement 41 übertragen. Vorzugsweise ist das Messgerät 20 dazu ausgebildet ist, im Start-Signal einen für die Gegenstelle, hier das als Kommunikations-Endstelle oder Gegenstelle fungierende OTN-Netzelement 43, bestimmten Steuerbefehl zum optischen Netzelement 41 zu senden. Der Steuerbefehl enthält eine Anweisung an das OTN-Netzelement 43, eine bestimmte Aktion auszuführen. Die bestimmte Aktion kann beispielsweise das Herstellen einer Prüfschleife betreffen. In diesem Fall kann das optische Netzelement 41 dazu ausgebildet sein, den im Start-Signal enthaltenen Steuerbefehl zu erkennen und den Steuerbefehl zum Beispiel in einer optischen Transporteinheit (OTE) über das optische Transportnetz 40 zu dem als Gegenstelle fungierenden OTN-Netzelement 43 zu übertragen. Das als Kommunikations-Endstelle fungierende OTN-Netzelement 43 ist dazu ausgebildet, den in der empfangenen optischen Transporteinheit enthaltenen Steuerbefehl zu erkennen und auszuführen, indem das OTN-Netzelement 43 beispielsweise eine Software basierte Prüfschleife einrichtet, um die von dem als Kommunikations-Endstelle fungierenden optischen Netzelement 41 kommenden Daten zurück zum optischen Netzelement 41 zu übertragen. Das OTN-Netzelement 43 kann ferner dazu ausgebildet sein, eine Aktions-Information, die die von dem OTN-Netzelement 43 ausgeführte vorbestimmte Aktion beschreibt, zu erzeugen, und den Steuerbefehl und/oder die Aktions-Information über das Datenkommunikationsnetz 60 zum Netzmanagementsystem 70 zu übertragen. Der Steuerbefehl und/oder die Aktions-Information werden dann im Netzmanagementsystem 70 zur weiteren Verwendung, insbesondere zur automatischen Dokumentation des Betriebszustands der Daten-Kommunikationsverbindung 100 gespeichert.

The previously regarding the in 1 The functionality of the communication system shown in section 10 is essentially also applicable to the system described in 2 The communication system shown is 10'. The following differences exist compared to communication system 10:

• The data communication link 101 runs between the two OTN network elements 41 and 43, which function as communication endpoints.
• A start signal, repeatedly transmitted signals indicating ongoing measurement, and a stop signal are transmitted directly from the measuring device 20 to the OTN network element 41. Preferably, the measuring device 20 is configured to send a control command to the optical network element 41 in the start signal, intended for the remote station, here the OTN network element 43 acting as the communication endpoint or remote station. The control command contains an instruction to the OTN network element 43 to perform a specific action. This specific action could, for example, involve establishing a test loop. In this case, the optical network element 41 can be configured to recognize the control command contained in the start signal and transmit the control command, for example, in an optical transport unit (OTE) via the optical transport network 40 to the OTN network element 43 acting as the remote station. The OTN network element 43, acting as a communication endpoint, is configured to recognize and execute the control command contained in the received optical transport unit. This is achieved, for example, by the OTN network element 43 establishing a software-based check loop to transmit the data coming from the optical network element 41, which also acts as a communication endpoint, back to the optical network element 41. The OTN network element 43 can further be configured to generate action information describing the predetermined action to be performed by the OTN network element 43 and to transmit the control command and/or the action information via the data communication network 60 to the network management system 70. The control command and/or the action information are then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 100.

In order to resume normal data transmission via the data communication link 100 after the measurement process, the measuring device 20 is preferably configured to send a control command to the optical network element 41 in the stop signal. This control command is intended for the OTN network element 43, which acts as the communication endpoint or counterpart. The control command contains an instruction to the OTN network element 43 to perform a specific action. This specific action could, for example, involve removing a software-based test loop. In this case, the optical network element 41 can be configured to recognize the control command contained in the stop signal and transmit the control command, for example, in an optical transport unit (OTE) via the optical transport network 40 to the OTN network element 43 as the counterpart. The OTN network element 43 is configured to recognize and execute the control command contained in the received optical transport unit by removing the previously formed software-based test loop. The OTN network element 43 can further be configured to generate action information describing the predetermined action performed by the OTN network element 43 and to transmit the control command and/or action information via the data communication network 60 to the network management system 70. The control command and/or action information is then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 100.

• Die Daten-Kommunikationsverbindung 102 verläuft zwischen den beiden Netzabschlusseinheiten 30 und 110, die direkt an das OTN-Netzelement 41 angeschlossen sind. Weitere OTN-Netzelemente sind an dieser Daten-KommunikationsVerbindung beteiligt.

The previously regarding the in 1 The functionality of the communication system shown in section 10 is essentially also applicable to the system described in 3 The communication system shown is 10". The following differences exist compared to communication system 10:

• The data communication link 102 runs between the two network termination units 30 and 110, which are directly connected to the OTN network element 41. Other OTN network elements are also involved in this data communication link.

A start signal, repeatedly transmitted signals indicating ongoing measurement, and a stop signal are transmitted by the measuring device 20, if present, via the network termination unit 30 to the optical network element 41. Preferably, the measuring device 20 is configured to send a control command to the optical network element 41 in the start signal, intended for the remote station, here the network termination unit 110 acting as the communication endpoint or remote station. The control command contains an instruction to the network termination unit 110 to perform a specific action. This specific action can, for example, involve establishing a test loop, particularly a software-based test loop. In this case, the optical network element 41 can be configured to recognize the control command contained in the start signal and transmit the control command directly to the network termination unit 110 acting as the remote station, for example, in an optical transport unit (OTE). The network termination unit 110, functioning as a communication endpoint, is configured to recognize and execute the control command contained in the received optical transport unit. This is achieved, for example, by establishing a software-based test loop to transmit data coming from the communication endpoint 30 or the optical network element 41 back to the optical network element 41 or the communication endpoint 30. The network termination unit 110 can also be configured to generate action information describing the predetermined action performed by the network termination unit 110 and to transmit the control command and/or action information via the OTN network element 41 and the data communication network 60 to the network management system 70. The control command and/or action information are then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 100.

In order to be able to use the data communication link 120 normally for data transmission again after the measurement process, the measuring device 20 is preferably configured to send a control command to the optical network element 41 in the stop signal. This control command is intended for the network termination unit 110, which acts as the communication endpoint or counterpart. The control command contains an instruction to the network termination unit 110 to perform a specific action. This specific action could, for example, involve removing a software-based test loop. In this case, the optical network element 41 can be configured to recognize the control command contained in the stop signal and transmit the control command directly to the network termination unit 110, for example, in an optical transport unit (OTE). The network termination unit 110 is configured to recognize and execute the control command contained in the received optical transport unit by removing the previously formed software-based test loop. The network termination unit 110 can further be configured to generate action information describing the predetermined action performed by the network termination unit 110 and to transmit the control command and/or the action information via the OTN network element 41 and the data communication network 60 to the network management system 70. The control command and/or the action information are then stored in the network management system 70 for further use, in particular for the automatic documentation of the operating status of the data communication link 120.

In 4 The flowchart shows the temporal sequence of an exemplary measurement operation with respect to the data communication link 100. The flowchart schematically illustrates that the measuring device 20 first transmits a start signal, which is preferably contained in a first binary pseudorandom sequence, then two binary pseudorandom sequences followed by a signal to indicate an ongoing measurement, then two more binary pseudorandom sequences followed by another signal to indicate an ongoing measurement, and finally two more binary pseudorandom sequences followed by a stop signal contained in a binary pseudorandom sequence.

Claims (12)

Procedures, in particular for the automatic detection and documentation of the implementation a measurement with respect to a data communication link (100, 101, 102) existing between a first communication endpoint (30, 41) and a second communication endpoint (43, 50), wherein the data communication link (100, 101, 102) runs at least via a first network element (41) of a core network (40) configured for data transmission, wherein the method comprises the following steps: a) connecting a measuring device (20) to the first network element (41); b) transmitting a first signal, which contains start information signaling the start of a measurement operation, from the measuring device (20) to the first network element (41); c) transmitting, after the measurement operation has ended, a second signal, which contains stop information signaling the end of the measurement operation, from the measuring device (20) to the first network element (41); d) after execution of step b) and before execution of step c), repeated transmission of a third signal, containing measurement operation information indicating an ongoing measurement operation with respect to the data communication link (100, 101, 102), from the measuring instrument (20) to the first network element (41); e) detection by the first network element (41) of the start information in the first signal, the stop information in the second signal and the measurement operation information in each third signal and transmission of the received start information, the received stop information and each of the received measurement operation information from the first network element (41) to a network management system (70) via a data communication network (60) separate from the core network (40), wherein the core network (40) and the data communication network (60) separate from the core network (40) support different communication protocols; and f) storing the information transferred in step e) in the network management system (70) to document the performance of a measurement regarding the data communication link. Procedure according to Claim 1 , wherein the core network (40) is a standardized optical transport network, in particular an optical transport network in accordance with the ITU-T G.709 standard. Procedure according to Claim 1 or 2 , wherein the procedure comprises the following steps: By responding to the start information transmitted in step b), the first network element (41) generates a first status information signaling that the current operating state is a measurement operation; by responding to the stop information transmitted in step c), the first network element (41) generates a second status information signaling that the measurement operation has ended and/or the data communication link is back in the normal communication operating state; the first and second status information are transmitted from the first network element (41) to the network management system (70) via the data communication network (60), which is separate from the core network (40); and the first and second status information are stored in the network management system (70) to document the execution of a measurement with respect to the data communication link. A method according to any of the preceding claims, wherein the first signal transmitted in step b), the second signal transmitted in step c), and each third signal transmitted in step d) each contain information for identifying the data communication link (100), wherein the information for identifying the data communication link (100) is transmitted from the first network element (41) to the network management system (70), and wherein the information for identifying the data communication link (100) is stored in the network management system (70) for the purpose of documenting the execution of a measurement with respect to the data communication link (100). Method according to one of the preceding claims, wherein at least the first signal transmitted in step b) contains at least one piece of information relating to the measurement and/or at least one piece of information characterizing the measuring instrument (20), wherein the at least one piece of information relating to the measurement and/or the at least one piece of information characterizing the measuring instrument (20) is transmitted from the first network element (41) to the network management system (70), and wherein the at least one piece of information relating to the measurement and/or at least one piece of information characterizing the measuring instrument (20) is stored in the network management system (70) for the purpose of documenting the execution of a measurement with respect to the data communication link (100). A method according to any of the preceding claims, wherein the data communication link (100) runs at least sectionally between the first network element (41) and a second network element (43) of the core network (40), and the method comprises the following steps: transmitting the information received in the first, second, and every third signal from the first network element (41) to the second network element (43) via the core network (40), and forwarding this information from the second network element (43) to the network management system (70) via the data communication network (60), which is separate from the core network (40); and Storing the received information in the network management system (70) to document the performance of a measurement regarding the data communication link. Procedure according to Claim 6 , wherein the information contained in the first, second and every third signal is stored in the first and/or second network element (41, 43). A method according to any one of the preceding claims, wherein the method comprises the following steps: i) transmitting, in step b), in the first signal at least one control command, which is intended for the second communication endpoint (43, 50) of the data communication link (100, 101, 102), wherein the at least one control command contains instructions for the second communication endpoint (43, 50) to execute a predetermined action; transmitting the at least one control command from the first network element (41) to the second communication endpoint (43, 50); and executing the predetermined action by the second communication endpoint (43, 50) depending on the at least one control command received. Procedure according to Claim 8 , wherein, depending on the at least one control command received, a check loop is established by the second communication endpoint (43, 50). Procedure according to Claim 8 or 9 , wherein the data communication link (100) runs at least sectionally between the first network element (41) and a second network element (43) of the core network (40) and the second communication endpoint (43, 50) is the second network element (43) of the core network (40), wherein the method comprises the following steps: transmitting the control command from the first and/or second network element (43) to the network management system (70) via the data communication network (60) separate from the core network (4); and storing the control command transmitted from the first and/or second network element (41, 43) in the network management system (70) for the purpose of documenting the execution of a measurement with respect to the data communication link. Procedure according to Claim 8 or 9 , wherein the data communication link (101) runs at least section by section between the first network element (41) and a second network element (43) of the core network (40) and the second communication endpoint (43, 50) is directly connected to the second network element (43) of the core network (40), wherein the at least one control command is transmitted from the first network element (41) via the second network element (43) to the second communication endpoint (50), wherein the method comprises the following steps: transmitting the control command from the first and/or second network element (43) to the network management system (70) via the data communication network (60) separate from the core network (40); and storing the control command transmitted from the first and/or second network element (41, 43) in the network management system (70) for documentation of the execution of a measurement with respect to the data communication link (100). A method according to any of the preceding claims, wherein the method comprises the following steps: Performing predetermined measurements with respect to the data communication link (100, 101, 102) between the first and second communication endpoints (30, 50) by means of the measuring device (20); and providing the measured values obtained by the predetermined measurements for further use.