EP1566039A1

EP1566039A1 - Method for diverting data packets when local link failures are identified

Info

Publication number: EP1566039A1
Application number: EP03785675A
Authority: EP
Inventors: Joachim Charzinski; Michael Menth
Original assignee: Siemens AG; Nokia Siemens Networks GmbH and Co KG
Current assignee: Nokia Solutions and Networks GmbH and Co KG
Priority date: 2002-11-29
Filing date: 2003-11-27
Publication date: 2005-08-24
Also published as: US20060045004A1; WO2004051957A1

Abstract

According to said method, routing information or a list of routing information is inserted or modified in the packet header of data packets, in response to a malfunction of the packet network, in order to avoid defective nodes or links. The data packets with modified headers are routed using the inserted routing information to avoid the network node that is not available. The routing information inserted in the packet header can be determined via the packet network with the aid of topological information. The invention allows a rapid response to malfunctions. Packet losses and delays in data transmission can thus be avoided immediately after the determination of the malfunction by routers adjoining the malfunction area, whereas in conventional packet networks, a problem-free data transmission can only be restored after the convergence of the modified topological information in the packet network.

Description

description

Procedure for redirecting data packets in the event of locally recognized link failures

The invention relates to a method, a network node and a central control node for rerouting a data packet transmitted at least over a section of a packet network.

The further development of packet networks, especially with regard to the quality features in the transmission of data packets, is currently a central field of activity for network specialists, switching technicians and internet experts.

The realization of quality features for real-time traffic over packet networks is of great importance. For a service with real-time transmission of data, e.g. Telephony or video on demand requires that the packet networks used for this purpose meet strict criteria with regard to quality of service features such as packet transmission times, maximum delay times for packets and packet loss rate in order to guarantee the required quality of service.

The forwarding of packets from node to node - usually referred to in the technical literature as "routing" - plays a central role for the reliability of packet transmission over packet networks. Conventional packet networks do not guarantee quality criteria. For example, current data traffic via the Internet is usually according to the order

Effort principle routed, ie that the transmission of data packets is carried out as efficiently as possible, but without guaranteeing quality criteria. As a result, data traffic over conventional packet networks is subject to large fluctuations, which are caused, for example, by bottlenecks or overload or malfunctions. Modern developments aim to increase the reliability of data traffic improve. A current approach for data transmission over the Internet is the so-called MPLS (Multiprotocol Label Switching) method, in the context of which connections are established end-to-end through the packet network - in this context one usually speaks of paths. The distribution of data traffic on a path basis allows better control of the traffic volume routed via the packet network, but is associated with a considerably greater complexity of the method.

In addition to preventing overload, the reaction of the network to malfunctions, e.g. failure of a connection section (usually referred to in the specialist literature as a link) or a router or node, is a decisive factor in determining whether quality of service characteristics can be maintained, especially with regard to data traffic under real-time conditions. In the world's most common packet networks, the so-called IP networks, two routing algorithms are primarily used for routing within domains or autonomous systems (AS), namely distance vector routing and link state routing. With distance vector routing, the distance is minimized in the sense of a metric for the respective destination. The routing table then contains the next station or the next hop in terms of the minimum distance to the respective destination. A router uses the distance information of its neighboring router to calculate the distance. Link state routing is based on the propagation or distribution of topology information or distance information using so-called link state packets in the entire network or the entire autonomous system. In the event of malfunctions, for example the failure of a node or a link, inconsistency in the routing tables or routing information held by the routers results in both methods. This inconsistency is gradually eliminated as part of the propagation of topology information. This is called convergence of the routing information. Networks converged with regard to the routing information are inconsistent and have completed their reaction to the incident. During the However, during the period of convergence of the network, the transmission of data is impaired, which usually leads to quality reductions. Rapid convergence of the network is therefore an important criterion for the efficiency of a routing algorithm. Because of the faster convergence, the link state algorithm is usually preferred to distance vector routing.

The object of the invention is to improve the response of packet networks to incidents.

The object is solved by the subjects of claims 1, 15 and 17.

According to the invention, a network node of a packet network determines that a second network node cannot be reached. This second network node has failed, for example, or the link leading to this second network node is faulty. The network node inserts or changes routing information into the packet header of a data packet that was originally supposed to be routed via the second network node that cannot be reached. The data packet is forwarded in accordance with the inserted or changed routing information in such a way that the path of the data packet does not lead via the faulty second network node.

The disturbed second network node is, for example, the next hop for the data packet, that is to say the next station or the next node on the way of the data packet through the packet network, with regard to the routing regulation for the data packet held by the first network node. The inserted routing information, which for example consists of the address of a network node, is then used for routing that avoids the failed second network node. The routing Information can, for example, be an alternative next

Reference hop, or a third node to which data packets are routed via another, undisturbed next hop. By explicitly specifying the third node, it is then on the path through which the data packet is routed to its destination. For example, this third node is given by an edge node of a routing domain or an autonomous system.

With various routing protocols such as OSPF (open shortest path first), the first network node does not have detailed information about the routing tables of the network nodes via which the data packet is routed in accordance with the inserted routing information. In the method according to the invention, it is nevertheless excluded that one of the network nodes downstream of the first network node routes the data packet to the disturbed node, as long as the downstream network nodes for which routing to the disturbed network node could be topologically supported support the method according to the invention and via unreachability of the disturbed node or the link failure. The support of the method by subsequent nodes is not necessary in the following further development, in which topology information of the packet network is used.

The further development of the invention provides for routing information to be provided in the network node which is based on information about the topology of the packet network, and the insertion of which ensures that no routing to the failed network node also occurs through the node downstream of the network node. The routing information based on the network topology - hereinafter referred to as a list of routing information - can be obtained from one or more node addresses for further routing. Routing on the basis of these addresses specifies a path which, in the context of the routing protocol used, cannot lead via the failed node. In modern networks, topology information is frequently exchanged routinely at predetermined time intervals between the network nodes. For example, link state routing provides for the periodic exchange of so-called link state advertisements (LSA), as a result of which topology information is propagated or distributed in the network. The exchange of “distance vectors” plays a similar role in distance vector routing protocols, as a result of which the topology information held at the network nodes is updated. With the aid of topology information, the routing information to be inserted into the data packet by the network nodes can be selected such that the data packet is routed on a path that does not lead via the failed network node, with subsequent nodes only supporting the method according to the invention in that the routing is carried out on the basis of the inserted routing information. The method can be extended to the failure of several network nodes, the routing information to be inserted then being determined in such a way that none of the failed nodes is on the way of the data packet. Another variant is to use the routing information to specify a path which avoids an environment of the failed node, it being assumed that the incident also affects the environment of the failed node.

The invention has the advantage that a quick reaction to accidents is possible. The convergence with regard to the topology information propagated in the network is no longer decisive for the smooth traffic of data packets within the network. It is useful to determine the length of time for the

Use of the method according to the invention in accordance with the convergence of the topology information within the packet network. After the convergence has been established, the disturbed node or the disturbed nodes are removed from the routing tables of the network nodes, so that the network's incident response according to the invention can be switched off. The procedure is flexible with regard to the network's response to faults. For example, one can react to the inaccessibility of one or more nodes, or even to the failure or inaccessibility of entire network areas. The method according to the invention is not restricted to special protocols. Current packet networks generally provide a structure that differentiates between routing within so-called domains or autonomous systems and routing between the different domains or autonomous systems. In this context, one speaks of intradomain routing and interdomain routing (intradomain routing or interdomain routing in the English-language specialist literature). The invention can be used in conjunction with any intra-domain routing protocols, such as, for example, OSPF (Open Shortes Path First) IS-IS (Intermediate System to Intermediate System), NLSP (NetWare Link Service Protocol) and PNNI (Private Network-to-Network) Interface) for link-state routing or RIP (Routing Information Protocol) and RTMP (Routing Table Maintenance Protocol) for distance vector routing, as well as for interdomain routing, for example in connection with the EGP (Exterior Gateway Protocol) or BGT (Bo- the Gateway Protocol) protocol (EGP is also used as a generic expression for interdomain protocols). The calculation or determination of routing information for the failure of one or more network nodes can, for example, be triggered at the network node by the notification of the failure or malfunction. Alternatively, routing information can be calculated in advance to avoid network nodes that cannot be reached and made available in routing tables of the network node. For example, the network node has a routing table which, in addition to a next hop for forwarding a data packet to a destination specified in the packet header of the data packet, contains a further entry with routing information or routing addresses. If the next hop cannot be reached, the routing addresses of the further entry in the routing table are then inserted into the packet header of the data packet, and routing based on these inserted addresses then leads to the failure of the failed node. The routing information for bypassing unreachable next hops need not be calculated when the incident is reported. The routing table entries can be determined with a list according to the invention with routing information during or immediately after the routing tables have been created. The calculation or determination can take place in the network node itself or at a central location or in a central control node. When calculating in a central location, it is necessary that the calculation information for the respective network nodes is propagated using a protocol. This disadvantage of additional traffic is offset by the advantage of less computing effort and fewer resource requirements for the network nodes.

An advantageous further development in the determination of routing information in the sense of routing via a path, which avoids an unreachable node is the complementary application of the insertion of routing information according to the invention in the packet header and the forwarding of the unchanged data packet to an alternative next hop. If it is found when determining the routing information for the routing according to the invention that the forwarding from the network node to another next hop is sufficient to avoid routing via the faulty network node, it is not necessary to place the routing information in the packet header insert. For example, in a routing table with a further entry for the treatment of incidents, in addition to a list with routing information according to the invention, the routing to an alternative next hop can be provided without modifying the packet header if this is sufficient to avoid the disturbed node.

Another development that covers a special case is the following: The list of routing information can be determined by calculating an alternative path to the destination that avoids the failed nodes. In special cases, it is not possible to calculate such an alternative case. For example, based on the existing non-converged topology information, an intradomain routing protocol can provide that all data traffic to a specific destination address leaves the network or the domain via the same fixed edge node. If this specified edge node fails, it is then not possible to calculate an alternative route to the destination of the data packet on the basis of the existing topology information, as long as no convergence of the topology information has taken place within the network after the edge node has failed. In this case, According to the development, provision is made to dispense with an alternative path determination and instead to determine a path according to the failure of the edge node under the criterion that this avoids the failed node. For example, the routing information would then provide routing or by means of the invention, the list of routing information, to rebroadcast the ^"data packet to a non-failed nodes. If the node is an edge node, the data packet can then be routed to the destination (which is located in another network) using an interdomain protocol. After the topology information has converged, a failed edge node would of course no longer be provided for routing to an external network destination, and the method according to the invention no longer needed to be used.

Another advantageous development provides that the network node following the first network node extract the routing information or the list with routing information in order to use it for routing data packets with the same destination but a different origin address. The subsequent network node is, for example, prompted by the routing information inserted in the packet header to forward the data packet to another next hop than the one provided in the locally available routing table. From the point of view of the subsequent network node, there is a malfunction for which the countermeasure has been taken that the data packet with the modified packet header is forwarded to another next hop. As a consequence, data packets with the same destination (ie usually the destination address is in the same network or the destination network is the same) as the data packet modified in the packet header must also be forwarded differently than intended in the local routing table. to avoid the unreachable node. The subsequent node can use the routing information extracted from the packet header for routing data packets with the same destination. Possibly. In the case of data packets with the same destination that have not already been modified in order to avoid the failed node, the extracted routing information or a part thereof relating to a subsequent node is inserted in the packet header in order to implement routing in the sense of avoiding the unreachable node. The subsequent node does not need to calculate an alternative route from topology information for data packets with the same destination.

Another special case is that in order to avoid a fault, a data packet should be sent back via the link via which it reached the network nodes. There are routing methods that do not allow the return of data packets, for example in the course of avoiding loops or delays. According to the invention, provision can be made to switch off the return lock in such a case.

A last special case is routing in a non-homogeneous network, which consists of routers with resources for the method according to the invention and routers which do not support the method according to the invention. The restriction that only a part of the routers has the functionality for the method according to the invention can then be taken into account when determining the routing information for insertion into the packet header of the data packet, in order to enable the method according to the invention even in non-homogeneous networks.

The invention is explained in more detail below in the context of an exemplary embodiment with reference to figures. Show it Fig. 1: A section of a packet network formed with routers and links

2: An entry in a routing table with an indication of an inventive reaction to a node failure

3: Indexing of lists for alternative routing in the context of an error reaction according to the invention in accordance with output nodes of the network

4: Use of the indexing corresponding to FIG. 3 for the routing entry according to FIG. 2

1 shows a section of a packet network on which 8 routers or nodes R1,..., R8 and the links L12,..., L78 connecting the routers are shown. Within the scope of the exemplary embodiment, it is assumed that the packet network is an IP (Internet Protocol) network. Packets sent from an originating node S and a destination node D, both of which may be outside the packet network, are considered. These packets should normally take the path S ... R1-L13-R3-L35-R5-L58-R8 ... D (i.e. without failures of links or nodes). In the following it is assumed that the link L35 of this route fails in the event of a fault. In classic IP routing, the packets between S and D would then be lost until after detection of the failure and distribution of the failure message to all nodes via a routing protocol, these nodes have calculated new routing tables that again have a valid route between S and D contain (referred to above as convergence of the network with respect to the propagated topology information).

It is assumed that the routers Rl, ..., R8 support the "loose source routing" option of IP. The node that detects the failure - in this case R3 - now extends the IP header of all packets to be sent to D by a field (source routing optioή) in which it is specified that these packets should be forwarded via nodes R2 and R4. R3 chooses node R2- as an intermediate node because the direct route to R4 would possibly lead via L35. R4 is specified as an additional intermediate node to avoid that router R2 packets to D over the route

L23-R3-L35- ... tried to forward. Router R2 does not need any information about link L35 failure. The method works regardless of whether router R2 has received an update of its topology information that includes the link failure or not. Router R4 did not need to be specified for further routing if router R1 could assume that router R2 routes all traffic for destination D via router R4. As a rule, such information is not available with IP networks. With normal IP routing according to OSPF or IS-IS, the network topology is known throughout the network, but not the routing tables of the individual nodes, since the "shortest-path" routing algorithm used is not deterministic and with the same length

(equally expensive) Because the selection of the path is implementation-dependent.

According to a development of the method, a node that detects a link failure assumes that the node behind it has also failed. The list of intermediate nodes is then selected so ^'that this node is avoided. In the present example from Figure 1, in accordance with this further development, router R3 would enter the intermediate nodes R2 and R6 (or R2 and R7) in the source routing list in the packet header of affected packets. Node leads for the method described with reference to FIG. 1

Rl for each entry in its routing table a list of intermediate nodes, via which the destination can still be reached if the next link or node fails. In the following, an algorithm is given which enables the determination of an alternative route. The algorithm runs locally in a node and only uses the information that is available to this node (e.g. topology information that was transmitted via link states agreements):

• For each entry D [i] in the routing table (i = 1, 2, ... r), r = number of entries in the routing table:

• Assumption: The next node (next hop) has failed. • Under this condition, search for the shortest route to destination D and enter all m nodes in this route (within the network under consideration) in a node list E one after the other.

• Add a last entry to the list E [m + l] = D [i]

For each entry E [j] in this node list, from the beginning, starting with the second last entry, i.e. j = m-l, m-2, ..., 2, 1 (m be the number of nodes on the way)

• Check whether the shortest route ¹ in the original network (without failure) leads safely from E [j] to E [j + 2] via E [j + 1]. • If yes: Delete E [j + 1] from the list, ie the entry is deleted and the list is shortened accordingly by one entry. Instead of j + 1 there is now the entry that was previously E [j + 2].

• If no: keep E [j + 1] in the list • Check whether the entry for the destination E [2] in the local routing table leads the node E [l] as the next hop. • If yes: remove E [l] from the list (ie E [2] becomes the new E [l], etc, see above)

• If no: keep E [l] in the list.

• Note the nodes remaining in the list as a list with "loose source routing" nodes in a field of the routing table assigned to D [i]

Here, safe means that the possible variants of the short-test path algorithm in the other network nodes are taken into account. That if there are multiple shortest paths from E [j] to E [j + 2] and not all of them contain the node E [j + 1], E [j + 1] is left in the list.

The algorithm results in the entries in the list being reduced to the minimum number of entries required to avoid the broken link.

According to this algorithm, the entry for D in the routing table of node R3 could have the content shown in FIG. 2. For destination D, the routing table sees the next one

Hop R5 before. If R5 cannot be reached, a list with entries R2 and R6 is provided. R4 is not included in the list because it is assumed that packets destined for router R6 are always routed directly to router R6 as part of a least cost metric router R4. According to the invention, the addresses of R2 and R6 are inserted in the packet header as part of the source route option.

According to a further development, instead of the destination node D, an output node or edge node of the network domain can function as the destination of the alternative route to be determined. The algorithm can then be used in the following modification:

• For each entry D [i] in the routing table: • Find the exit node AN of the network area under consideration on the way to D [i]. Assumption: From a network area, the traffic to a destination network is always routed via a well-defined exit node. • Enter this node in an initial node table if it is not already included. Let the index of the entry be k, so the entry itself is A [k].

• Enter the index k in a corresponding field of the routing

Table for entry D [i]. • For all output nodes A [k], k = 1, 2, ..., number of output nodes in the network area under consideration:

• Run the algorithm from above, with the list of

Detour node in the list A [k] and not in the routing table.

The next steps are analogous to the version of the algorithm specified first.

3 shows lists with alternative routes to each output node of the network domain under consideration. The lists are indexed for more efficient reference. The third entry corresponds to the example considered with reference to FIG. 1. It is assumed that router R8 is an edge node.

FIG. 4 then shows the entry corresponding to FIG. 2 in the routing table. The use of the index to refer to the alternative route is an economical solution insofar as the same alternative route is generally used for a large number of end addresses D (or the packets are routed via the same output node). A repeated statement the entire list for each associated end address is avoided.

Claims

claims

1. A method for rerouting of data packets transmitted by at least one part of a packet network formed with a plurality of network nodes, in which

a first network node (R3) determines that a second network node (R5) of the packet network is unavailable, is modified by inserting or changing at least routing information in the packet header of the data packet for forwarding the data packet avoiding the second network node (R5), and

- The data packet is forwarded by the first network node in accordance with the inserted routing information while avoiding the second network node (R5).

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

- That the second network node (R5) is the next hop of the data packet with regard to forwarding the data packet through the first network node (R3) in the case of an undisturbed network.

3. The method according to claim 2, characterized in

a list with routing information is stored in the first network node (R3) and is assigned to the next hop of the data packet,

- That the routing information of the list is inserted into the packet header of the data packet when the next hop is not available, and - That the data packet is sent from the first network node (R3)

In accordance with the inserted routing information is forwarded.

4. The method according to any one of the preceding claims 1, characterized in

- That the routing information or the routing information is given by network nodes referencing address information.

5. The method according to any one of the preceding claims, characterized in that the routing information or the list of routing information is determined by means of topology information about the packet network in accordance with the avoidance of the unreachable second network node (R5).

6. The method according to claim 5, characterized in

- That the routing information or the list of routing information is determined by calculating a route for the routing of the data packet under the boundary condition that the route avoids the unreachable second network node (R5).

7. The method according to any one of the preceding claims, characterized in that the first network node (R3) comprises a routing table for forwarding data packets to a destination address via a next hop,

that routing information or a list with routing information is determined in the sense of avoiding the next hop for at least some of the destination addresses in the routing table, and

- that in the event that a next hop cannot be reached for data packets with destination addresses for which the next hop that cannot be reached is intended as the next hop in the routing table, the corresponding routing information or routing information included in the list is inserted in the packet header, and - The data packets are forwarded by the first network node (R3) in accordance with the inserted routing information or the inserted routing information.

8th . A method according to claim 7, characterized in that

- That for destination addresses in which the routing information or list with routing information determined in the sense of avoiding the next hop comprises only one address information that references another next hop, instead of inserting the address information into the packet header of data packets to be forwarded to the destination addresses it is provided that if the next hop cannot be reached, the data packets are forwarded unmodified to the specific next hop in each case.

9. The method according to any one of the preceding claims 7 or 8, characterized in that the routing information or the list of routing information is determined by means of topology information either in the first network node (R3) or a central control node, and

- That when determining the routing information or the list of routing information in a central control node

Routing information or the list of routing information are transmitted to the first network node (R3).

10. The method according to any one of the preceding claims, characterized in

- that the packet network is based on the IP protocol, and

- That the routing information or the routing information is inserted as address information in the sense of loose source routing in the IP header of the data packet.

11. The method according to any one of the preceding claims 7 to 10, characterized,

- That the routing information or the list of routing information is determined by means of topology information about the packet network in accordance with the avoidance of two or more network nodes that cannot be reached.

12. The method according to any one of the preceding claims, characterized in that

- That the period after a link or node failure during which the method for avoiding the unreachable second network node (R5) is used is limited, and

- The limit for the period of execution of the method after a link or node failure is given by the time of convergence of the topology information of a large number of the network nodes of the packet network.

13. The method according to any one of the preceding claims, characterized in that the routing information or the routing information in the packet header of the data packet is extracted from a further third network node (R2, R4) following the first network node (R3) modifying the packet header, and the extracted routing information or the extracted routing information from the subsequent third network node (R2, R4) are used for routing further data packets in the sense of avoiding at least one failed network node or link.

14. The method according to any one of the preceding claims, characterized in

that some of the network nodes of the packet network have resources for carrying out the method, and

- That the routing information or the extracted routing information reference address information from network nodes with resources for carrying out the method.

15. Network node with means for performing a method according to one of the preceding claims.

16. Network node according to claim 15, characterized in

with a routing table for forwarding data packets to a destination address via a next hop, wherein at least some of the destination addresses are assigned routing information or a list with routing information, by inserting them into the packet header, data packets can be forwarded while avoiding the respective next hop.

17. Central control node for determining the routing information or the list with routing information by means of topology information for performing a method according to one of claims 1 to 14.