EP2638672A1

EP2638672A1 - Method for improving the quality of data transmission in a packet-based communication network

Info

Publication number: EP2638672A1
Application number: EP12702460.2A
Authority: EP
Inventors: Johannes Riedl; Matthias Scheffel
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2011-01-28
Filing date: 2012-01-20
Publication date: 2013-09-18
Also published as: DE102011003321A1; US20130315062A1; US9191334B2; CA2825830A1; WO2012101054A1; CA2825830C; CN103329490A; CN103329490B

Abstract

The invention relates to a method for improving the quality of data transmission in a packet-based communication network comprising a plurality of network nodes (K). Each of the network nodes (K) has a number of ports (P) with which at least one queue (Q) is associated respectively, and by means of which ports a communication connection (KV) to another network node (K) can be produced. According to the method of the invention, at least the queues (Q) of those ports which are arranged, in the network nodes (K), along respective communication paths that are formed in the communication network, are monitored for their queue length. In addition, a degree of overload of the affected port(s) (P) is determined from the queue length, and on the basis of the degree of overload of the communication path(s) (PF1, PF2, PF3) running across the affected overloaded port (P), a runtime delay (delay) and/or a delay variation (jitter) in the data transmission can be inferred. Finally, the overload amount rises above a predetermined threshold value for at least one of the communication paths (PF1, PF2, PF3) running across an overloaded port (P). An alternative communication path (PF2') is configured, the overloaded ports (P) thus being bypassed.

Description

description

Method for increasing the quality of data transmission in a packet-based communication network

The invention relates to a method for increasing the quality in a packet-based communication network comprising a plurality of network nodes, wherein each of the network nodes has a number of ports, each of which at least one queue is assigned and the one Kommunikationsver ^¬ binding to another Network node can be made. The invention further relates to a network node of a packet-based communications network and a packet-based Kommu ^¬ nikationsnetz having a plurality of network nodes.

In many applications distributed over a communications network, the data transfer must not exceed certain limits in terms of end-to-end delay and / or jitter, in order to achieve the desired quality of service of the application. This is particularly true in the industrial field formed in communication networks, for example for a Fabrikautomatisie ^¬ tion, a process automation or energy automation. Currently, only TDM (Time Division Multiplexing) based network technologies can meet given delay and jitter value requirements along communication paths formed within the communication network. In principle, suitable network technologies are SDH (Synchronous Digital Hierarchy) or ATM (Asynchronous Transfer Mode) networks. Due to their complexity and the high costs, especially when scaling, they are not useful in many application scenarios.

For reasons of complexity and low costs, even with scaling, the use of packet-based communication networks is therefore desirable. Such communication networks are, for example, Ethernet or IP (Internet Protocol) -based communication networks. A problem with packet-based com- However, communication networks consists of the fact that, in principle, no guarantees with regard to delay and / or jitter can be guaranteed. While there are elaborate extensions of Ethernet in the Industrial Ethernet (for example (isochronous real-time transmission ^¬ IRT) for PROFINET) announced that a deterministic behavior of the communications network via TDM Nachbil ^¬. However, this technology can only be used with the use of special hardware and a high degree of configuration effort.

It is therefore an object of the present invention to specify a method with which the quality of the data transmission in a packet-based communication network can be increased. Furthermore, a network node of a packet-based communications network is to be indicated which allows an increase in the quality of the data transmission in the packet-based communications network. Finally, it is also an object of the invention to specify a packet-based communication network which has a high quality of data transmission.

These objects are achieved by the method according to the features of claim 1, a network node with the features of claim 12 and a packet-based

Communication network with the features of claim 13. Advantageous embodiments will be apparent from the dependent claims. The invention provides a method for increasing the quality of data transmission that detects a plurality of network nodes in a packet-based communication network, each network node having a number of ports to which to ^¬ least one queue is assigned and a communication link to another network node can be produced. In the method, at least the queues of those ports are monitored for their queue length, which ports in the network nodes are respectively along are arranged in the communication network educated communication paths. From the queue length a Überlas ^¬ tion measure is determined for the one or more ports in question, from the congestion measure for the relevant or overloaded port running communication paths on a run ^¬ time delay (delay) and / or delay variation (jitter) in the data transmission can be closed. If the overload ^{measure exceeds} a predetermined threshold value, an alternative communication path bypassing the overloaded ports is set up for at least one of the communication paths, which is routed via an overloaded port.

The invention further provides a network node of a packet-based communications network having a plurality of Netzkno ^¬ th, wherein the network node comprises a number of ports, which has at least one queue assigned in each case and via which a communications link to another network node can be established. The network node comprises a first means for monitoring the queues of those ports for their queue lengths, which ports are arranged in the network nodes along respective communication paths formed along the communication network. The network node further comprises a second means for determining the Überlastungsma ^¬ SLI from the queue length for the port or ports in question.

The invention further provides a packet-based Kommunikati ^¬ onsnetz comprising a plurality of inventively designed network nodes and a network management entity for establishing communication paths and / or alternative communication paths using routing mechanisms in the communication network. The network management entity comprises a third means are closed by the from the resultant by a jewei ^¬ intelligent network node overload fault for the or the respective, congested port ongoing communication paths to a propagation delay (Delay) and / or Verzögerungsva ^¬ riation (jitter) in the data transmission can. The network management entity further comprises a fourth means by which, when the overload fault exceeds a pre ^¬ give threshold value, for at least one of Kom ^¬ munikationspfade which is guided over a congested port, an alternate communication path, bypassing the congested ports can be set up.

With the invention can be a determinism in packet ^¬ oriented communication networks, such as, for example, achieve on the Internet Protocol-based communication networks or Ethernet. This results in a high convolution quality with regard to delay and / or jitter for the communication paths formed in the communication network. An advantage of the procedure according to the invention is that a complex calculation of absolute delay and / or jitter values is not necessary in order to be able to determine that there is a delay and / or jitter-critical situation within the communication network. This applies in particular ^¬ sondere assuming that in the otherwise almost empty communication network (ie there is no overload or jam situation) the delay and / or jitter requirements are met without any problems. A further advantage is that hardly any modification is necessary in the network node in order to implement the procedure according to the invention. A further advantage is that the method ensures a Ska ^¬ lierbarkeit in large communication networks. This is ensured because, with the method according to the invention, it is necessary to monitor delay or jitter values only per queue and network node, but not per communication path.

In an expedient embodiment, the alternative communication path is set up bypassing those nodes which comprise at least one overloaded port. This redirects the route of the alternate communication path around the node with the congested port. This can be advantageous if the performance of the entire network node is already adversely affected by the overload of a port.

According to a further embodiment, one of the following queue lengths is processed to determine the congestion measure: an average queue length, the average queue lengths being calculated from the time average of a plurality of acquired queue lengths of a queue over a predefined period of time; and / or a ma ximum queue length and / or an effective ^¬ waiting queue length, which is calculated from temporally preceding and refreshes rush queue lengths. Based on the specified queue lengths suitable communication paths for delay or jitter-critical communication ^¬ paths can be determined.

According to a further expedient embodiment, the communication paths and / or the alternative communication paths are set up by a higher-level network management entity using routing mechanisms. The network management entity serves to actively create communication paths in the packet-based communication network. The active creation of communication paths by the network management entity can, for example, be analogous to MPLS (Multi Protocol Label Switching). As a criterion for good or bad communication paths, the queue lengths of several ports of the network nodes are doing OF INVENTION ^¬ dung as used. The network management entity may be formed by a central computer, a control unit of one of the network nodes or a plurality of computers and control units.

In the further embodiment, the queue length of the ports of the plurality of network nodes are polled at predetermined intervals by the higher-level network management entity, wherein the network management entity determines the extent of congestion for each of the ports. Alternatively, the queue lengths of the ports of the plurality of network nodes become at predetermined intervals and / or as a function of exceeding a predetermined global or network node-specific threshold value from the network nodes to the higher-level network management entity, wherein the network management entity determines the extent of congestion for each of the ports.

It is also expedient if, when setting up the new communication path, at least the overload dimensions of those ports which are arranged in the network nodes along the new communication path are taken into account. When creating a new communication measure, the result is not always the shortest connection between the source node and destination node when setting up the new communication path. Rather, the utilization of the respective network nodes or the ports located in a potential communication path is taken into account as well.

In this context, it is expedient if a first lower threshold value for the overload fault (or the War ^¬ tesch long) is defined those ports which are located in the network nodes along the new communication path, which, if exceeded, the new communication path is set up such that the nodes are ignored for the new communication path having at least one congested port whose congestion exceeds the first threshold or the congested ports are disregarded by nodes whose congestion exceeds the first threshold.

In a further embodiment, a second, higher threshold value for the overload fault (or queues ^¬ length of the queue) is defined those ports which are located in the network nodes along the new communication path, determines if exceeded for existing Kom ^¬ munikationspfade alternative communication paths and set up. By providing the first and second relatively higher threshold value, the load of a network node or an overloaded port can thus be specifically controlled with regard to the data transmitted via it. Depending on the determined queue length, under certain circumstances not only the new communication path is routed specifically around the congested port or the respective network node, but also a communication path already going over the congested port is diverted.

According to a further expedient embodiment, the overload dimensions (or the queue lengths) are monitored as a function of a traffic class of the relevant queue. If low-priority traffic occurs in addition to high-priority traffic, the latter can cause increases in delay and / or jitter in high-priority traffic. For example, this may be caused by an unfavorable scheduler implementation in the network node or by the arrival of a high priority data packet while still sending a long low priority data packet. Such critical situations caused by the low-traffic traffic can be reliably detected by considering the queue lengths of different traffic classes. Through the above beschrie ^¬ bene strategy of diverting certain communication paths overall utilization can be improved in the communication network, creating a determinism in the packet-based communications network to increase the quality of data transmission can be achieved in the result.

A further embodiment provides that end-to-end values for the propagation ^{delays ¬} are arranged from the determined congestion measures or the waiting queue lengths of the enqueue queues, which are arranged in the network node along respective communication paths formed in the communication network tion and / or the delay variance are determined on the relevant communication path. The procedure according to the invention is thus based on the dynami ^¬ rule use of queue lengths of the ports of the network nodes to identify delay and / or Jitterkritischen situations in connection with the regular polling of the queue lengths or corresponding messages through the network nodes if specified thresholds are exceeded. Based on the information about the queue lengths of the ports of the network nodes present in the communication network, suitable communication paths for delay or jitter-critical traffic flows are calculated. A Vor ^¬ part of the procedure is that a ^¬ independence of the detailed scheduler implementation or of a used scheduler concept is given. The invention will be explained in more detail below with reference to an embodiment in the drawings. Show it:

1 shows a communication network according to the invention with a plurality of network nodes and a higher-level network management entity,

FIG. 2 shows the communication network from FIG. 1, in which three paths set up by the network management instance are shown by way of example, FIG.

FIG. 3 shows the communication network of FIG. 2 in which one of the network nodes reports an overloaded port to the network management entity, FIG.

FIG. 4 shows the communication network according to FIG. 2, in which one of the original communication paths has been placed on an alternative route, and FIG

Fig. 5 shows the communication network of Fig. 2, in which a new communication path has been established.

Fig. 1 shows an inventive communication network with egg ^¬ ner plurality of network nodes K and a Netzwerkmanagementin- punch NM. The network nodes K are numbered from 1 to 8, wherein the numbers represent a respective address of the network node K. Each of the network nodes K has a number of ports P, via which a communication link KV to another network node K can be established. In the present embodiment, the number of outgoing from a bone ^¬ K th communication links the number of ports, wherein a respective node may in principle have a larger number of ports than the communication links corresponds. Only for the marked with the addresses 1 and 5 node K ports P are provided with their reference numerals. Depending on the type of communication network, the communication links KV can be line-based or wireless ^NAT . In particular, in the latter case, it is possible that form other communication links between the nodes K than those shown in Fig. 1.

The node K is ^{preceded by} the already mentioned network management entity NM. The network management entity, which is formed for example by a central computer, is able to exchange data with the network node K via respective communication links KVN. The communication links KVN, which are shown in FIG. 1, are merely logical in nature and need not exist directly between the respective network node K and the network management entity NM. Are the manner in which data between the network Manage ment ^¬ instance and the network node K exchanged (wireless or wired) is for the present invention is of minor importance.

In order for a data transmission between a functioning as a source node network node K and functioning as a destination node network node K of the communication network predetermined Anfor ^¬ requirements for data transfer with respect to a end-to-end delay (Delay) and / or delay variation (jitter-ter) meet to can 1 is performed in the principle paketba ^¬ overbased communication network of FIG. under control of the network management entity NM active management of the Communication network created communication paths. In principle, the end-to-end delay and jitter may be particularly critical when due to a Paketzwischenspei- assurance (so-called Queuing) ^¬ node in the network nodes along K egg nes particular communication path between source and destination packet traffic jams are caused containing varying forward each times in the individual network nodes. The reasons for this include a blocked off ^¬ gangs ports by sending another package or the pre- ferred control other cached packages with higher priority. Since the delay is usually not de ^¬ terministic, variable delay and jitter values can arise. On the one hand, the task of the network management instance is to set up and to administer the communication paths formed in the communication network. On the other hand, it is the task of the network management entity to monitor at least the queues of those ports at their queue length, which ports in the network nodes are arranged along respective communication paths formed in the communication network. From the queue length, the network ^¬ management entity may determine an overload fault for the ports, wherein in the overload fault for the one or current via the relevant, congested port communication paths often a delay and / or Jitterproblem can be closed in the data transmission. Usually, several waiting ^¬ queues (queues) for each port P of a network node are present, the one or more priorities (traffic classes) are arranged conces-. The priorities are defined, for example, via IEEE 802.1P Class of Service (CoS) or IP Type of Service (ToS). Exceeds the overload fault concerned ei ^¬ NEN predetermined threshold value, that is the queue length of a queue of a port is greater than the predetermined threshold, it is for at least one of the communication ^¬ paths, which is guided through a through burdensome port, an alternate communication path, bypassing the congested Ports set up. These paths are chosen so that the critical ports P or network nodes are not used.

The overload measure can be a value directly proportional to the queue length. Likewise, the overload level of the queue length, z. For example, the number of bytes of time before the queue is processed, and so on.

FIG. 2 shows in an example the communication network described in FIG. 1, in which three communication paths PF1, PF2, PF3 are set up by the network management entity NM. The communication path 1 runs from the network node 1 via the network nodes 5 and 2 to the network node 3. The communication path PF2 runs from the network node 1 via the network nodes 5 and 6 to the network node 8. The communication path PF3 runs from the network node 4 via the network nodes 5 and 6 8 to the network node in the selected embodiment, all 3 communication paths PF1, PF2 and PF3 are thus passed over the Netzkno ^¬ th 5, wherein the communication paths PF2 and PF3 further through a common port PI (5) are passed. As a result, a packet jam may occur at the port PI (5), which may result in a delay and / or jitter for both the communication path PF2 and the communication path PF3. If a degree of congestion formed at the port PI (5) exceeds a predefined threshold value, then according to FIG. 3 the network node 5 transmits a message N to the network management entity NM. The network management entity NM can infer from the congestion measure for the communication paths PF2, PF3 running via the port PI (5) to a possibly occurring delay and / or jitter problem. Because of the Netzwerkmana ^¬ ABERGEMENT instance NM performs a reconfiguration of the two communication nikationspfade PF2, PF3. In the present Ausführungsbei ^¬ play an alternate communication path PF2 'is created for the communication path PF2 extending from the network node 1 via the network nodes 2 and 3 to the network node. 8 To set up the communication paths, the network management entity NM uses known routing methods in principle. The communication paths can be set up for example by direct entries in Layer 3 routing or Layer 2 forwarding tables. A device or adaptation can also be realized by an adaptation of the metrics influencing the routing or forwarding tables. These can be, for example, Open Shortest Path First (OSPF) weights or link costs and priorities in Rapid Spanning Tree (RSTP) or Multiple Spanning Tree (MSTP). Corresponding mechanisms and procedures are known to those skilled in the art. The data transmission from a source node to a destination node can he follow ^¬ first along preset default paths. This means a default path is initially inde ^¬ gig of the queue length of the queue, along which the communication path is formed. The network management entity NM only intervenes when a problem situation has been identified during the continuous monitoring of the network node K and its queues.

Requests for the establishment of new communication paths can be edited so that a new communication ^¬ path avoids the critical ports or network nodes. This is exemplified in Fig. 5, wherein over the communica tion ^¬ paths according to Fig., A new communication path PF4 from the network node 1 via the network node 4 and 7 to the hub 6 3. Although the shortest route from network node 1 to network node 6 would pass through port PI (5) of network node 5, a path through network nodes 4 and 7 is selected to avoid the congestion on port PI (5) of network node 5.

For the establishment of new communication paths, it is helpful to set a first, a lower, and a second, compared to a higher threshold. At the If the first, low threshold value is exceeded, new communication paths, such as the communication path PF4, which is added to the existing communication paths PF1, PF2 'and PF3, are set up via alternative network nodes. In the event of ^¬ requirement which the second, higher threshold and existing communication paths are partially diverted.

In principle, it is also possible for one or more threshold values for each of the central network node individually to defi ^¬ kidney, so that a network node K transmits a message to the Network Management NM instance, when the respective limits are exceeded. This makes a constant query of the states by the management entity superfluous and spares communication resources.

For the determination of the congestion measure an average queue length is preferably used, with the mitt ^¬ sized queue length calculated from the time average queue lengths more sensed over a predetermined period of time. As a result, strong fluctuations can be avoided. Alternatively, a maximum queue length can also be defined, which may correspond, for example, to the second, higher threshold value from above. Similarly, the use of an effective queue length to determine the congestion measure is possible, with the effective queue length being determined from temporally preceding and current queue lengths. As a result, the history of the queue length can be taken into account, wherein z. B. an exponential smoothing can take place.

In a further embodiment, it is alternatively possible to monitor the queue length for certain traffic classes, eg. As a particular priority class, as they typically carry the delay and jitter sensitive data traffic

In addition to considering an overshoot or undershoot of average, maximum or effective queue lengths by the overload fault and absolute end-to-end values for the delay or jitter can be derived from this by the Ma ^¬ management system instance. To this end, several ^¬ re delay units are added: the overload fault offset against the respective bandwidths of the links; the delays in the network nodes due to switching operations, which may be estimated or measured; Ausbreitungsverzö ^¬ struggled (propagation delay) at all involved communication links, which may be estimated or measured (for. Example, by means of appropriate mechanisms, which are standardized in the context of time synchronization in accordance with IEEE 1588 or 802. las). This is advantageous in particular when current delay and / or jitter values have to be reported to an application causing the data traffic or when a communication path may only be established under the secondary condition of not exceeding a specific delay or jitter value.

Claims

claims

A method of increasing the quality of data transmission in a packet-based communication network comprising a plurality of network nodes (K), each of the network nodes (K) having a number of ports (P), each associated with at least one queue (Q) and a communica tion ^¬ connection (KV) to another node (K) can be prepared, in which

- At least the queues (Q) of those ports are monitored for their queue lengths, which ports (P) in the network node (K) along respective communication paths formed in the communication network are angeord ^¬ net;

determining from the queue length an overload measure for the port or ports concerned (P), wherein from the congestion measure for the communication path (s) (PF1, PF2, PF3) running via the respective congested port (P) to a run-time delay and / or delay variation (jitter) in the data transfer can be concluded;

if the overload measure exceeds a predetermined threshold, for at least one of the communication ^¬ paths (PF1, PF2, PF3), which is guided over an overloaded port P, an alternative communication path

(PF2 ') bypassing the congested ports (P).

2. Method according to claim 1, in which the alternative communication path (PF2 ') is set up bypassing those network nodes (K) which comprise at least one overloaded port (P).

3. The method of claim 1 or 2, wherein one of the following queue lengths is processed to determine the congestion measure:

an average queue length, wherein the mitt ^¬ sized queue length from the time average sev- calculate the acquired queue length of a queue over a given period of time; and / or a maximum queue length; and or

an effective queue length, which is determined from temporally preceding and current queue lengths.

4. The method according to any one of the preceding claims, wherein the communication paths (PF1, PF2, PF3) and / or the alternative communication paths (PF2 ') are set by a higher-level network management entity NM.

5. The method of claim 4, wherein the queue lengths of the ports (P) of the plurality of network nodes (K) are queried at predetermined intervals by the higher-level network management entity (NM), wherein the network management entity (NM) for each of the ports (P ), the overload fault ermit ^¬ telt.

6. The method of claim 4, wherein the queue lengths of the ports (P) of the plurality of network nodes (K) at timed intervals and / or depending on the exceeding of a predetermined global or network node individual threshold from the network node (K) to the parent network management entity (NM), wherein the network management entity (NM) determines the extent of congestion for each of the ports (P).

7. The method according to any one of claims 4 to 6, wherein in the establishment of a new communication path (PF4) at least the overload measures of those ports (P) are taken into account, which are arranged in the network node (K) along the new communication path (PF4).

8. The method of claim 7, wherein a first, low threshold for the congestion of those ports, which in the network node along the new communication path (PF4) are arranged is defined, above which the new communication path (PF4) is adapted such that the nodes are allowed (K) for the new communication path (KV) au ^¬ SSER eight which at least congested an above have port whose overload fault exceeds the first threshold or

disregard the congested ports of nodes (K) whose congestion exceeds the first threshold.

9. The method of claim 8, wherein a second, higher threshold for the congestion of those ports, which are arranged in the network nodes along the new communication path (PF4) is defined, when exceeded for existing communication paths (PF1, PF2, PF3) alternative

Communication paths (PF2 ') are determined and set up.

10. The method according to any one of the preceding claims, in which a monitoring of the overload measures in dependence of a traffic class of the relevant queue (Q) he follows ^¬ .

11. The method according to any one of the preceding claims, wherein from the determined congestion of those queues (Q), which in the network node (K) along respective communication paths formed in the communication network (KV) are arranged end-to-end values be determined (KV) for the Laufzeitver ^¬ delay and / or delay variance on the respective communication paths.

12. Network node of a packet-based communications network having a plurality of network nodes (K), wherein the network node (K) a number of ports (P), each having at least ei ^¬ ne queue (Q) is associated, and on the nikationsverbindung a communication ( KV) to another network node (K) can be produced, comprising

a first means for monitoring the queues of those ports for their queue lengths, which Ports (P) are arranged in the network node (K) along respective communication paths formed in the communication network;

a second means for determining a Überlastungsma ^¬ SLI from the queue length for the or the Subject Author ^¬ fenden ports (P).

13. packet-based communication network comprising a plurality of network nodes (K) according to claim 12 and a network management ^¬ instance (NM) for establishing communication paths (PF1, PF2, PF3) and / or alternative communication paths (PF2 ') in the communication network, wherein the network Manage ment ^¬ instance comprising:

a third means by which obtained from the from a jeweili ^¬ gen network node (K) overload fault for the one or current via the relevant, congested port (P) communication paths (PF1, PF2, PF3) in a propagation time delay (Delay) and / or Delay variation (jitter) in the data transmission can be closed;

a fourth means whereby, when the congestion measure exceeds a predetermined threshold, for at least one of the communication paths (PF1, PF2, PF3) routed over an overloaded port (P), an alternative communication path (PF2 ') bypassing the congested one Ports (P) can be established.