EP1925135A1 - Method for modifying a route for data packets in a packet-oriented communication data network and apparatuses therefor - Google Patents

Abstract

The invention relates to a method for modifying a route for routing data packets in a packet-oriented data communication network, in which the route between a first device (ED1) and a second device (ED2) is set up using at least one interposed device (A1, A2), each of the devices (ED1, ED2, A1, A2) is allocated an individual network address of the data network, and the interposed device knows an individual address of at least the first and second devices or of a further interposed device (A1, A2, LR1, LR2), wherein the interposed device (A1; A2) can determine that it is an interposed device and communicates an item of routing information - that an upstream device is intended to communicate directly with a downstream device (A2; LR2) downstream of the interposed device (A1; A2) - to the upstream device, and the upstream device moves the route past the interposed device to the device downstream of the latter.

Description

A method of modifying a route for data packets in a packet-oriented communications data network and apparatus therefor

The invention relates to a method for modifying a route for data packets in a packet-oriented communication data network according to the preamble features of patent claim 1 or to a network device for carrying out such a method.

Various communication data networks allow subscribers or their terminals to become increasingly mobile. As a result, the terminals are often not located in the network indicated by their IP address (IP: Internet Protocol) as a locator. In order to maintain routes between a terminal and another terminal despite the current location of the terminal, explicit routing information, such as tunnel encapsulation or source routing information at points, also known as anchors, is provided. be installed within the network. The anchor points are interposed as being within the route

Means are responsible for forwarding data packets to the nearest suitable device, in particular the next suitable intermediate device, so that the data packets ultimately reach the destination terminal. An example of such an anchor point is a mobile IP home agent that holds information to send traffic for a particular terminal to its current network location. This introduces some measure of directional uncertainty and inefficiency into the data path from the source of a data packet to its destination. As more and more devices and networks enable mobility, the number of anchor points and uncertainty levels along a single data path will increase, further reducing routing efficiency. Such an exemplary scenario for establishing a route for data packets in a packet-oriented communication data network is sketched in FIG. The method illustrates a case where a mobile terminal MP as a terminal communicates with a corresponding node CN as a second terminal through two home mobility agents HA1, HA2. In the first home agent HAl forwarding state information for the mobile appointment MT is maintained and in the second home agent HA2 is a forwarding state information for the

Knot CN held. In this example, second mobile routers MR1, MR2 provide a current access point for the mobile terminal MT and the node CN, respectively. That is, the two mobile routers MR1, MR2 form the location, which allow a delivery of packets to these two terminals.

Source and destination address fields for data packets which are transmitted between the mobile terminal MT and the node CN are visualized by way of example next to the respective links. In the illustrated scenario, traffic from the mobile terminal MT is encapsulated in a backward tunnel to the first anchor point HAI by the first mobile router MRl, and the second mobile router MR2 terminates the tunnel used for traffic transport to the current location of the node CN , A second header section with source and / or destination address fields is required on the data path between the respective mobile router MR1, MR2 and its associated anchor point HA1 or HA2 in order to exchange data packets between them via the data network.

While this solution ensures that data packets are even delivered to the destination address, as the mobile routers change their access points to the network, routing inefficiency becomes a problem introduced, through which the entire traffic must pass through two fixed points in the network, the two home agents HAl, HA2, regardless of the physical topology of the network. This routing inefficiency has a number of disadvantages. In particular, it is disadvantageous that the expanded data path can have a greater latency and can have a limited bandwidth compared to a more optimal route. It is also disadvantageous that the extended or extended data path can lead a route over networks which are unreachable, whereas a completely optimized data path would directly have a connectivity between the two communicating end points. In the case of an optimal route, the traffic of a subscriber station would be routed as a terminal directly between the two mobile routers MR1, MR2, which allow the connectivity for the mobile terminal MT and the node CN, as sketched in FIG.

To simplify the description, the following terminology is used below. An explicit forward state is understood to be a state in a device on a data path which is set up in order to forward data packets to the current location of the terminal in a forward direction. A terminal device is understood to mean a subscriber station, an application server, etc., which generate or receive corresponding subscriber data or application data as data. This includes in particular mobile terminals, desktop machines, etc. A topologically independent locator is understood to mean a locator which is allocated by a terminal requesting an explicit forward state to be installed at points in the network to route the traffic correctly to a terminal. For example, a terminal may allocate a care-off address, which identifies a current access point of a mobile node, from the home network of a mobile router, wherein the Home network of the mobile router explicitly holds the forward state to allow a route to the network, which is assigned to the mobile router. An anchor point is understood to mean a node on the data path which makes known a reachability for the topologically independent localizer and includes an explicit forward-oriented state for routing traffic to a terminal device via a local router. A topologically allocated localizer is understood to be a localizer in which the forward state is always optimized for routing to the address, so that no explicit forward-oriented state is required by the network. The topologically allocated localizer is assigned to a local network address.

Route optimization solutions have been developed for specific cases, assuming specific signaling protocols.

For example, the so-called Mobile IP supports as

Protocol route optimization in both forward and backward directions as follows. As can be seen in Fig. 4, in the downstream direction of a data stream from a node CN to a mobile terminal MT, the mobile terminal MT informs the node CN of its care-off address, its current address, and its current topologically allocated localizer. The node CN can then direct traffic directly to the mobile terminal MT, bypassing a previously used anchor point Al. This requires that node CN, as a terminal, support the appropriate signaling and maintain the explicit forward state locally. The mobile terminal MT is also responsible for maintaining the explicit forward state in the node CN as its location changes. As can be seen from Fig. 5, in the uplink direction of a data stream from the mobile terminal MT to the node CN, the mobile terminal MT locally makes a decision to route data directly to the node CN. That is, the mobile terminal MT ignores the explicit forward state it is holding indicating that it should tunnel traffic to its anchor point A in a backward direction. According to the basic Mobile IP, the mobile terminal MT sends the packet only directly to the node CN. Depending on the source address that is used, there may be requirements associated with an input filter.

As can be seen from FIGS. 1 to 5, data packets are respectively transmitted with a corresponding source address and a destination address, wherein the device designation used as an example is mapped as an example.

When such mechanisms are associated with a variety of anchor points and possibly networked

Access points are to be considered for the terminal, a variety of requirements with respect to particular of the input filter can be seen, as shown in FIG. 6 can be seen. In these considerations, a local router is to be understood as a unit applicable only to terminals, and the local routers are always to be used only as terminal access points at the beginning or end of a data path with one or more intermediate devices in the form of anchor points ,

FIG. 6 shows in the left-hand section a spatially distributed arrangement of different units in the form of three terminal devices ED1-ED3, three local routers LR1-LR3, which serve as access stations for the terminals ED1-ED3, and three anchor points A1-A3, which serve as intermediary devices are connected in the data path between the local routers LR1-LR3. The right Side of Fig. 6 shows the transmission of data packets and signaling between these components.

The first terminal device ED1 communicates via the first local router LR1, which manages a topologically allocated localizer associated with the first terminal device ED1, the first local router LRl holding a forward-looking state assigned to this address. The first terminal EDl also holds a topologically independent address, which is managed by the first anchor point Al, so that the entire traffic intended for the first terminal device ED1 passes through the first anchor point A1. The first local router LRl, in turn, has a topologically allocated localizer associated with it, which is managed by the second local router, which maintains a forward-looking state to support routing to and from that locator. The third terminal ED3 has a topologically independent locator, which is offered by the third anchor point A3, and a topologically allocated locator, which is managed by the third local router LR3.

The non-optimized route is illustrated by the initial state of the sequence of events sketched on the right. The traffic is explicitly routed from the first local router LRl to the first anchor point Al, eg tunnelled. While passing the data through the second local router LR2, they are also explicitly routed to the second anchor point A2. Therefore, there are two levels of uncertainty as to the direction to take into account before the traffic can be routed to the actual destination address. On the data path to the third terminal ED3, another level of non-unique direction is introduced since the destination address of the traffic used by the first terminal ED1 to reach the third terminal ED3 is the topologically independent locator which is the third anchor point A3 is routed and then explicitly routed to the topologically allocated locationizer managed by the third local router LR3.

Mobile IP optimization may be used by the two endpoints to remove some of the non-unique directional determinations along this data path. This would be done in six steps shown in Fig. 6. In a first step, the first local router LRl sends a route optimization to the third terminal ED3 indicating that traffic should be sent to the first terminal ED1 via a topologically allocated localizer. In a second step, the data path between the first terminal device ED1 and the third terminal device ED3 is no longer explicitly routed via the first anchor point A1. In a third step, the third local router LR3 sends a route optimization message to the first terminal device ED1, which informs it about the topologically allocated localizer for the third terminal device ED3. In a fourth

Step 2, the second local router LR2 sends a route optimization message to the third terminal ED3 informing them about another topologically allocated localizer that traffic for the first terminal ED1 should be routed over it.

In a fifth step, traffic from the first terminal device ED1 to the third terminal device ED3 is now explicitly routed via the third local router LR3. In a sixth step, traffic from the third terminal ED3 to the first terminal ED1 is now explicitly routed via the first local router LR1.

It should be noted that Mobile IP can be used theoretically in this way, but this is not

Represents default behavior and would require that the terminals EDL - ED3 notify messages regarding route optimizations of intervening nodes along of the data path and also understand and handle forward conditions for multiple intermediate nodes. However, this would have a variety of disadvantages. Thus, the terminal equipment would have to master the signaling for route optimization according to Mobile IP. In addition, the terminal equipment would have to be able to maintain and manage a much more complex explicit forward state, for which an ordered list of anchor points would have to be managed. In addition, all decisions regarding route optimization would have to be made locally within the local routers, which, however, would not necessarily have adequate information for it, since, for example, an operator policy for the subscriber currently being managed might preclude performing route optimization.

The object of the invention is to propose an alternative method for modifying a route in a communication data network as well as preferably suitable facilities.

This object is achieved by the method for modifying a route having the features of patent claim 1 or by a network device for carrying out such a method having the features of patent claim 10. Advantageous embodiments are the subject of dependent claims.

Accordingly, what is preferred is a method for modifying a route for routing data packets in a packet-oriented data communication network, wherein the route is established between a first device and a second device via at least one intermediary device, wherein the intermediate device does not function as an endpoint is configured for the data packets and is located in a data path between the first device and the second device, each of the devices is assigned an individual network address of the data network, and the intermediary device is an individual address of at least the first and the second device or another intermediate device knows or can derive from a format of the data flow along the route. Advantageously, the method is characterized in that the intermediary device derived from the format and / or data packet information of the data packets routed along the route can determine that it is an intermediary device, and that the intermediary device has routing information that is upstream Device to communicate directly with a downstream device behind the intermediary device, or communicates a knowledge of an individual address of the downstream device behind the intermediary device to the upstream device and that the upstream device, the route at the intermediate device communicating this way over to this downstream device flips.

Such a method is advantageous in which the first device is a first terminal device and the second device is a second terminal device which communicate directly with one another and / or directly via these individually assigned network access devices. Such a method is advantageous in which, starting from the first device, one of the subsequently interposed devices is taken from the original route step by step. Such a method is advantageous in which prior to the transfer of the route for removing such an intermediary device, this downstream device is checked with regard to operator policies and / or relationships of trust for allowing the transferred route. Such a method is advantageous, in which the interposed device to be removed from the first device as a

Terminal device and / or to an access device as the first device in addition to the address as routing information of a subsequently interposed Establish a recommendation to relocate the route to this returns. Advantageous is such a method in which an access device of a first or a second terminal device as intermediary device or devices connected therebetween store original route information for use in the event of a later failure of a switched connection between two devices of the intermediary devices. Advantageous is such a method in which the original route or route information to the original route is maintained in an intermediary facility and / or a terminal access device for routing data in the event of a failure of a new connection resulting from the transfer , Advantageously, such a method, in which an access device of a second terminal at the end of the route after completion of the shortening of the route by assignment informs the front-facing institutions concerned of topological changes and / or posted failed connections. Advantageously, such a method, in which return from an intermediary device or an access device after redistributing the route towards a first terminal return packets in the packet header information used to reference the original connection and / or their assignment as a credential to Identification of the device sending the data packet and no longer included in the current route.

Preferred is a network device for carrying out such a method with a memory device for storing its own unique network address and a unique network address of a downstream device on an originally established route and with a

Control means for determining whether the network device is an intermediary device in the route and if so, for notifying the address of the downstream one Device or corresponding routing information to an upstream device for transferring the route through the upstream device directly to the downstream device, bypassing this network device itself.

Advantageously, such a network device or intermediate device, which is designed as uniquely addressed device for receiving data packets and for forwarding received data packets to a subsequent downstream network device and / or to a subsequently interposed device. Such a network device or intermediate device which is designed as an access device for a radio-supported mobile terminal device is advantageous.

Ideally, according to the method, a route is provided for subscriber data traffic which is highly optimized and in which data packets are transmitted directly between the two mobile routers as access devices for the terminal equipment. According to the method, a solution is proposed, which assumes that an intermediate device in the form of a particular anchor point can recognize that a route optimization is possible. It provides a robust communication structure using routing protocols, which are preferably provided by default and serve to set up a non-optimized route, which allows a simple procedure and implementation. Described is a way to configure appropriate explicit forward state information in relevant nodes along the data path. The procedure is applicable to a wide variety of scenarios beyond the concrete scenario described. An implementation is possible in any scenarios in which a device along a data path is able to determine that a more efficient route is possible, in which case the device uses, in particular, information which is available in tunnels. Headers are present. However, other information sources such as explicit routing header information, etc. may also be used. An implementation is also possible in cases where there is a hierarchical topology.

Such optimization of the data path provides better latency and potentially greater bandwidth along the data path between the communicating nodes, particularly between the communicating terminals. It also eliminates the need to route traffic over an infrastructure that may or may not be reachable. This allows for a more robust communication structure, preferably using the standard routing protocol, which is commonly used for routing to the anchor points as intermediary devices. What is provided is a simple method wherein topology information is maintained outside of an inter-network intermediary area.

While other route optimization techniques exist, they are designed for very specific mobility cases. In contrast, the method described makes possible route optimization by means of existing techniques and a large number of advantages. This keeps the end users or end stations away from otherwise required complexity. Terminals as subscriber terminals do not need to provide additional support, as required by MIPv6, for example. Therefore, the end system will experience improved end-to-end forwarding, with the background signaling required between the stations remaining transparent in the data path area for the terminals.

It is also possible to include the decisions of the operators regarding policies. Providing a Vertex trimming as a service may be implemented specifically by the operators and a policy prescribed by them to accommodate current load situations and other criteria such that a device interposed as a vertex will allow or deny such route optimization depending on, for example, network usage can.

It is possible to set up optimal or optimized routes between facilities and networks. The establishment of optimal or optimized routes can thereby be made possible step by step, that is, the removal of mobility anchor points as intermediary devices from the forwarding forward data path can be performed in several consecutive steps, as a strategy that requires a total optimization in one step does not require.

It is also possible advantageously to remove or remove individual points if an error exists or occurs on a corresponding data path to them. The removal of anchor points as intermediary devices from the forwarding forward data path is equivalent to the removal of individual error points, as taken in isolation for a MIP

Home agent would be the case. If a tunnel endpoint fails along the forward data path, a different forward-biased data path can be recovered and used due to earlier vertex trim information.

An interruption operation can also be supported if, for example, the two local routers lose the connection or connectivity with the additional Internet but are still peered together. For example, if two spotted routing groups lose connectivity to the Internet but are still able to communicate with each other, general communication is still possible. An application to any topologies and networks is possible. The solution is particularly applicable to any network supporting IP transport, packet encapsulation and packet decapsulation and corner trimming integrated into an IP-based mobility management protocol.

Also offered are more ways to aggregate traffic that traverses the same network segments.

In particular, for VPN (Virtual Private Network) solutions that aggregate traffic, route optimization based on such vertex trimming can be used to provide load balancing and also to provide specific forward-looking services ,

It is also preferable to support on-the-fly traffic without packet loss. If an anchor point is taken out as an intermediary device based on the rule "make-before-break". That is, when new tunnels are set up, a returned route could be done on-the-fly without packet loss.

Advantageously, it is also possible to decouple upwardly and downwardly directed data streams via corresponding routes. For bi-directional traffic, an uplink and a downlink direction can be handled independently of each other, unlike Mobile IP, where a bidirectional tunnel is usually established.

An embodiment will be explained in more detail with reference to the drawing. Show it:

FIGS. 1A-1C each show two terminal devices which have a respective local router assigned to them communicate with each other, wherein an initial route via two intermediate anchor points leads and wherein in the individual figures, two process steps for optimizing this route are outlined and

FIGS. 4 to 6 show various such devices in which a route specification according to the prior art takes place.

As can be seen from FIG. 1A-IC, a transmission of data packets from a first terminal device ED1 to a second terminal device ED2 is carried out via a communication network. It is between the two terminals EDL, ED2 and others

Network devices established a communication via a respective local router LRl or LR2. The communication between the first terminal device ED1 and the first local router LR1 and the communication between the second terminal device ED2 and the second local router LR2 is preferably carried out via radio interfaces. Shown are schematically source and destination addresses or corresponding information in headers, which are used for the routing of data packets. For simplicity, the respective device reference numerals are used instead of usual addresses.

Fig. IA shows an initial route which leads in a conventional manner from the first terminal EDl to its associated local router LRl and thereafter to a first anchor point Al as a first intermediary device. From the first anchor point Al, data packets are forwarded to a second anchor point A2 and from there to the second local router LR2, which is assigned to the second terminal ED2. The second local router LR2 transmits the received data packets to the second terminal ED2. Data packets from the second Terminal ED2 to the first terminal EDl are transmitted via the correspondingly reversed data path.

FIG. 1B shows a first optimization procedure in which the first anchor point Al, as the first intermediate device, recognizes that a bypass is possible and corresponding information for redirecting the route around it to the first local router LR1 as the one upstream of it Device transmits. The first local router LRl then sends further data packets via a correspondingly flipped route instead of the first anchor point Al directly to the second anchor point A2, wherein the second anchor point A2 forms a device downstream of the first anchor point Al in the original route.

FIG. 1C shows a further optimization step, in which the second anchor point A2, as a second intermediary device on the data path, correspondingly recognizes that further optimization and its own environment is possible. The second anchor point A2 then initiates a method according to the optimization step described above. Finally, the route is therefore established by the first local router LRl directly to the second local router LR2, bypassing the first and second anchor point Al, A2 as now no longer directly interposed devices.

Proposed is thus a vertex trimming, in which anchor points from an end-to-end data path between two terminals, for example a mobile terminal and a node, can be performed stepwise without any interaction of these nodes or terminals. What is needed for a node along the data path is preferably only one means or means for detecting and ensuring that it is an anchor point as an intermediary device and that it can itself decide to optimize away from the existing data path. In the preferred embodiment, for explicit routing, tunnel headers (tunneling Head sections), but this is not mandatory. Source routing, IPv6 routing headers or an explicit host can be used in the anchor points and in the access points (PoAs) instead of acting the same way.

In the embodiment illustrated in FIG. 1A, initially the two terminals ED1, ED2 communicate with each other using topologically independent localizers, as illustrated by corresponding addresses or information EDI TIL and ED2 TIL in the packet headers. The first local router LRl encapsulates and routes a data packet received from the first terminal ED1 explicitly via the first anchor point A1, correspondingly indexing a topologically allocated localizer EDI TAL as an address of the first local router LRl in the packet header. Advantageously, the topologically allocated localizer EDL TAL can be shared by a plurality of terminals, which are represented by the first local router LR1. However, this is not illustrated for the sake of simplicity.

The first anchor point Al directs the data packet in the forward direction in the network, where it is routed to the second anchor point A2 due to the second topologically independent localizer ED2 TIL. The second anchor point A2 is the device which offers accessibility for the desired address space. The second anchor point A2 then explicitly routes the data packet to a second topologically allocated address ED2 TAL, which is the current location of the second local router LR2, which offers the accessibility of the second terminal ED2.

As can be seen from FIG. 1B, the first anchor point A1 indicates to the first local router LR1 that it no longer receives the traffic through it, the first anchor point Al, but can route directly to the second anchor point A2. Accordingly, the first local router LRl starts to send the traffic directly to the corresponding address, the second topologically independent locator ED2 TIL, the routing being via the second anchor point A2, since this is the node in the network which has reachability for the given address offering.

Before the first local router LRl can begin forward routing of data packets along the newly formed alternative route, it preferably performs a check on the functionality and / or properties of the new candidate anchor point, which may optionally also be done in a previous step , The new candidate anchor point is formed by the second anchor point A2. In checking, in particular, available trust relationships and operator policies can be checked, which define the use of certain network services. Subsequently, the first local router LRl may confirm vertex trimming to the second anchor point A2 and, if necessary, send additional information for enabling tunneling between the first local router LR1 and the second anchor point A2. In particular, after confirmation of the vertex trimming a corresponding association between the second anchor point A2 and the first router LRl can be established.

In a subsequent step illustrated in FIG. 1C, the route is further optimized. The second anchor point A2 knows that it has explicit routing information for the second terminal ED2 and can make the decision to exclude itself from the data path by the second anchor point A2 sharing this explicit routing information with the first local router LRl , The forwarding of the explicit routing information is performed by the second anchor point A2 to the first local router LRl, since the second anchor point A2, the address of the first local router LRl from the Incoming packet headers can be specified as sender details. The second anchor point A2 correspondingly sends a returned message to the first local router LR1 and provides it with the explicit routing information indicating that the second terminal ED2 has specific routing information

Traffic using the second topologically independent address ED2 TIL should be sent directly via the second topologically allocated address ED2 TAL associated with the second terminal ED2, which is represented by the second local router LR2. Other tasks to be performed are the same as those of the previously described corner trim step.

Such a method advantageously makes it easy to restore old routes in the event of a failure

Error. For example, in the example visualized in FIG. 1C, the second local router LR2 could fail for some reason. Instead of the long and winding through the network route over the first and second anchor point Al, A2 shown in FIG. IA, the first local

Routers LRl preferably fall back directly to the route, which is partially optimized and bypasses only the first anchor point Al, so that a data path according to FIG. 1B remains usable for routing traffic. In this regard, either the tunnel between the first local router LR1 and the second anchor point A2 may still be left in operation for immediate use, or the first local route LR1 could include a memory, in particular cache, in which previous routes are stored which can be tried after a failure corresponding to a transmission of data packets for connection establishment.

The number of steps of possible vertex trimming, in principle, increases with an increasing number of anchor points as intermediary devices in the

End-to-end data path too, and this also applies in the case of eg networked (nested) topologies. In the preferred procedure is gradually gradually each eliminates an anchor point as an intermediary device at each step of vertex trimming.

As soon as an optimized, in particular optimal route has been set up, that is to say in the illustrated example in particular a tunnel has been set up between the first local router LR1 and the second local router LR2, it is the task of the second local router LR2 to determine the explicit forward state in those devices keep them now, keep them. In this case, these are both the second anchor point A2 and the first local router LRl, which should be informed regarding topologically allocated localizers, if such should change.

To ensure that the first local router LRl knows or has detected that a backward message was generated by any device along the data path, a so-called nonce or cookie may be inserted in its packet headers, for example the

Key field in a GRE (Generic Routing Encapsulation) header, such information being able to be echoed back to the local router by the node sending the returned message. Such an approach prevents out-of-the-data-path nodes or other unauthorized nodes from sending traffic as a traffic denial-of-service attack attempt in a reverse direction.

For triggering a backward request message, the following aspects are preferably taken into account. One of the anchor points Al, A2 may decide to send such a request message substantially whenever it wishes to obtain basic header information in a traversing IP data packet and / or additional policy related information. There may be opportunities which cause an anchor point Al, A2 to send an update and / or the situation that the second local router LR2 is moving. In this case, the second anchor point A2 could make the choice to send another returned message. It is also conceivable that in this case, the first local router LRl falls back to the data path of the standard routing, if it detects that the explicit route information that was supplied to him, is not current. Advantageously, error messages are also exchanged between the state holding devices, such as an error message that the destination is unreachable or the state is out of date. It can also be considered that the topologically allocated address may change for a particular end-user service. In such a case, a new access point and possibly a new anchor point will be established in the forwarding data path. In such a situation, the standard forwarding data path is used using the topologically independent locator for uplink and downlink data traffic. In subsequent steps, it is then necessary to again eliminate anchor points as intermediary devices from the forward path as described above.

Preferably, the tunnel entry point, for example, the first local router LRl in the present embodiment, support the so-called "make-before-break" rule to avoid packet loss. In this sense, the backward tunnel is established before a backward routing of data packets can actually take place.

Claims

claims

A method for modifying a route for routing data packets in a packet-oriented data communication network, wherein

the route between a first device (EDL) and a second device (ED2) is established via at least one intermediate device (A1, A2), wherein the intermediate device (A1, A2) is not configured as an endpoint for the data packets and is located in a data path between the first device (EDI) and the second device (ED2),

each of the devices (ED1, ED2, A1, A2) is assigned an individual address, and the intermediary device (A1, A2) has an individual address of at least the first and the second device (ED1, ED2) or another intermediate device ( Al, A2, LR1, LR2) or can derive from a format of the data flow along the route, characterized

- that the intermediary device (Al; A2) derived from the format and / or data packet information of the data packets routed along the route can determine that it is an intermediary device, and

that the intermediary device is to communicate routing information that an upstream device (EDL, LRI, Al) directly to a downstream device (A2, LR2) behind the intermediary device (Al, A2), or a knowledge of an individual address of the device downstream device (A2, LR2) behind the intermediate device (A1, A2) communicates with the upstream device (ED1, LR1, Al), and - that the upstream device (ED1, LRL, Al) routes the route at the intermediary device that communicates with it (A1; Al; A2) over to this downstream device (A2; LR2, ED2).

2. The method of claim 1, wherein the first device (EDL) is a first terminal and the second device (ED2) is a second terminal directly to each other and / or directly via these individually associated network access devices (LRL, LR2 ) communicate.

3. The method of claim 1 or 2, in which, starting from the first device (EDL, LRL) stepwise one of the subsequently interposed devices (Al, A2) is taken from the original route.

4. A method according to any preceding claim, wherein prior to switching the route to take out such an intermediary device (Al, A2), said downstream device (A2; LR2) checks for operator policies and / or trust relationships for allowing the transferred route becomes.

A method according to any preceding claim, wherein the intermediate device (A2) to be removed is connected to the first device (EDL) as a terminal and / or to an access device as the first device (LRl) in addition to the address as routing information of a following Intermediate device (A2) a

Recommendation for transferring the route to this returns.

A method according to any preceding claim, wherein an access means (LR1, LR2) of first and second terminals (ED1, ED2), respectively, as intermediary means or intermediary means (Al, A2) stores original route information for use in the case a later failure of a switched connection between two of the intermediary devices.

7. The method according to any one of the preceding claims, wherein the original route or a route information to the original route in an intermediate Device (Al, A2) and / or an access device (LR1, LR2) for a terminal device is maintained for routing data in the event of a failure of a new connection resulting from the transfer.

8. The method according to any preceding claim, wherein an access device (LR2) of a second terminal (ED2) at the end of the route after completion of shortening of the route by assignment of the upstream affected by allocation devices (LRl, Al, A2) posted topological

Changes and / or posted broken down connections informed.

9. The method according to any preceding claim, wherein by an intermediate device (Al, A2) or a

Access device (LRL, LR2) after assignment of the route in the direction of a first terminal (EDl) returned data packets in the packet header receive information used to indicate the original connection and / or their assignment as a

Proof of Entitlement to identify the device sending the data packet and no longer included in the current route.

10. network device (Al, A2) for carrying out a method according to any preceding claim with

a memory device for storing its own unique network address and a unique network address of a downstream device (A2, LR2) on an originally established route and

a control device for determining whether the network device (A1, A2) is an intermediary device in the route and, if so, for notifying the address of the downstream device (A2, LR2) or a corresponding routing information to an upstream device (LR1, Al) for transferring the route through the upstream device directly to the downstream Device (A2, LR2) bypassing this network device (Al, A2) itself.

11. Network device according to claim 10 and / or intermediate device according to one of claims 1 to 9, which is designed as uniquely addressed device for receiving data packets and for forwarding received data packets to a subsequent downstream network device and / or to a subsequently interposed device.

12. Network device according to claim 10 or 11, which is designed as an access device (LRL, LR2) for a radio-controlled mobile terminal.