EP2695364A1

EP2695364A1 - Method for addressing messages in a computer network

Info

Publication number: EP2695364A1
Application number: EP11713987.3A
Authority: EP
Inventors: Michael Tietsch; Christian Correll; Heinrich HAAGER
Original assignee: Unify GmbH and Co KG
Current assignee: Unify GmbH and Co KG
Priority date: 2011-04-01
Filing date: 2011-04-01
Publication date: 2014-02-12
Also published as: US20160301659A1; US9401892B2; US10158604B2; WO2012130263A1; CN103329507A; CN109600454A; US20130282924A1

Abstract

In a method for addressing messages in a computer network in which two different types of address are used, wherein at least one first network element (4, 5, 6, 7, 8) uses exclusively a first type of address, at least one second network element (14, 15, 16, 17, 18) uses exclusively a second type of address and at least one third network element (9, 10, 11, 12, 13, 14) uses both types of address, at least one third network element (9) is a communication terminal which, besides its function as a communication terminal, also performs a function as an address converter for messages for which said communication terminal is neither the original sender nor an ultimate recipient.

Description

Method for addressing messages

in a computer network

description

The invention relates to a method for addressing messages in a computer network. As the number of subscribers in computer networks increases, the types of addresses in such computer networks may reach capacity limits. A change of the address types can then be unavoidable. An example of this is the conversion of addressing in the Internet from so-called IPv4 addressing to IPv6 addressing. From now on, more and more (sub-) networks will have to be upgraded to IPv6 addressing, as most recent estimates suggest that no new IPv4 addresses will be available next year.

On the other hand, there will be a coexistence of IPv4 and ΙΡνβ addresses or corresponding subnets for many years to come. Due to the large number of existing installations, a few years, perhaps ten or even twenty years, will pass before the last IPv4 network element is shut down. During this transition period, both types of addresses will have to be used side by side. For certain services, for example based on the Session Initiation Protocol voice and video services (called VVoIP services), there are already converters between the two types of addresses, often in the form of so-called Session Border Controller (SBC) with a so-called integrated media gateway (MGW).

IPv4 provides an address space of just over four billion IP addresses (2 ³² = 4,294,967,296) that can be used to address computers and other devices

(Http://de.wikipedia.org/wiki/IPv6). In the early days of the Internet, when there were only a few computers that needed an IP address, this was far more than adequate. Due to the unforeseen growth of the Internet, there is a shortage of addresses today. On February 1, 2011, IANA assigned the last two free-to-use networks to the Asian Regional Internet Registry APNIC; Finally, according to a 2009 agreement, on February 3, 2011, the remaining address space was distributed evenly to the regional address allocation points. In addition, there is no further IPv4 address space available to the regional address allocation points. A daily updated forecast by APNIC's chief scientist shows that APNIC, the first regional Internet registry, will no longer be able to provide addresses to the Internet community as of July 2011.

The historical development of the Internet raises another problem: Due to the fact that the awarding of IPv4 address space has changed several times over the years, it is now highly fragmented, ie frequently several non-contiguous address areas belong to the same organizational entity. This, in conjunction with today's classless inter-domain routing strategy, results in long routing tables on which memory and processors of the routers must be laid out in the core area of the Internet. In addition, IPv4 requires routers, checksums each recalculated packet, which represents a further processor load.

For these reasons, the IETF began work on IPv6 in 1995. In December 1998, IPv6 officially became the successor of IPv4 with the publication of RFC 2460 on the Standards Track.

The key new features of IPv6 include: a) An increase in the address space of IPv4 with 2 ³² («4.3 billion = 4.3 · 10 ⁹ ) addresses to 2 ¹²⁸ (= * 340 sextillion = 3.4 · 10 ³⁸ ) Addresses in IPv6, ie magnification by a factor of 2 ⁹⁶

b) Simplification and improvement of the protocol framework (header data); This is especially important for routers.

c) A stateless automatic configuration of IPv6 addresses; Stateful methods such as DHCP become obsolete when using IPv6 in many applications

d) the so-called "Mobile IP" and simplification of

Renumbering and multihoming

e) An implementation of IPsec within the IPv6 standard. This enables encryption and verifying the authenticity of IP packets. For IPv4, IPsec support is only optional.

f) Support of network technologies such as Quality of Service and Multicast. The main motivation for increasing the address space is to maintain the end-to-end principle, which is a central design principle of the Internet: Only the end nodes of the network should have active protocol operations. The network between the end nodes is only responsible for forwarding the data packets. (The Internet un ^¬ differs here significantly from other digital data transmission networks such. As GSM.) Therefore it is neces- agile, that each network node is globally unique addressable.

Today's common methods such as Network Address Translation (NAT), which currently bypass the IPv4 address shortage, violate the end-to-end principle. They allow the connected computers only outgoing connections, from the Internet they can not be contacted easily. Also rely IPsec or protocols on higher layers such. As FTP and SIP partly on the end-to-end principle and are only limited with NAT or functional by means of additional solutions. For home users in particular, IPv6 means a paradigm shift: instead of having to assign a single IP address from the provider and having to connect several devices to the Internet via NAT, the user gets globally unique IP address space available for an entire subnetwork Each of its devices can get an IP address from this one. This makes it easier for end users to actively participate in the network by offering services; In addition, there are no problems caused by the address rewrite of NAT.

The present invention has for its object to provide a technical teaching to solve the problems associated with the situation described. This object is achieved by a method or by a product according to one of the independent claims. Advantageous further Formations of the invention form the subject of dependent claims.

According to the invention, a method for addressing messages in a computer network in which different types of addresses are used is provided, wherein at least a first network element uses only a first type of address, at least a second network element exclusively a second type of address and at least a third network element both types of addresses.

In this case, at least one third network element is a communication terminal which, in addition to its function as a communication terminal, also performs a function as an address converter with respect to messages for which this communication terminal is neither the original sender nor a final recipient.

In this context, a computer network is a network in which messages are exchanged between network elements by means of addresses. An important example of such a computer network is the Internet, in which messages are exchanged in the form of packets by means of so-called IP addresses between network elements.

Other important examples of computer networks in the sense of the present description are modern telephone systems. These fulfill their tasks by means of the so-called IP technology (Internet Protocol), in which the individual terminals are no longer connected by means of their own wiring to the telephone system, but like PCs (personal computer) are connected by means of a data network. In IP networks, the payload (generally digitized Speech data) are combined into data packets and provided with a sender address and a destination address, whereupon the network infrastructure makes the delivery of the data packet to the terminal by means of this destination address.

The usual while IPv4 (Internet Protocol version 4) has an address space of 2 ³² (= 4,294,976,296) possible addresses, which currently is already exhausted to a large extent ^¬. The further development of IPv4, the so-called IPv6 which is intended to resolve this limitation, offers a considerably larger address space of 2 ¹²⁸ possible addresses. IPv6 is in "Internet Protocol, Version 6

Specification; RFC2460 standardized the IETF. The connection of (partial) networks, each with a different Internet Protocol (IPv4 and IPv6), presents a problem which in the SIP environment according to the prior art by means of the ICE protocol (English: Interactive Connectivity Establishment, http : // tools. ietf.org/html/draft-ietf-mmusic-ice-19), whereby it is necessary that all participating terminals can act in accordance with the ICE protocol and one which can be reached by all the terminals involved Server makes the forwarding of the user data. It turns out to be disadvantageous that the ICE protocol must be used in all participating terminals, which may require complex changes to the control software of each device.

EL MALKI, Karim [et al.]: "IPv6-IPv4 Translation Mechanism for SIP-based Services in Third Generation Partnership Project (3GPP) Networks, Network Working Group", Internet Draft, December 2003,

URL: http: // tools. ietf. org / html / draft-elmalki-sipping3gpp-translator-00, discloses a method for bidirectional address translation in SIP-controlled data streams between ΙΡνβ-capable data terminals and IPv4-capable data terminals.

In this context, a network element is to be understood as a device capable of transmitting and / or receiving messages in a computer network. Examples of network elements are communication terminals, such as Internet telephones, computers, routers, switches and other network elements required or suitable for operating a computer network.

In this context, a communication terminal is a network element whose main purpose is to allow a subscriber to communicate over a computer network, in particular to allow that subscriber to send messages and receive messages in that computer network. Important examples of communication terminals are Internet telephones, computers, especially notebooks, smartphones and similar devices.

In this context, the term address translator is to be understood as a network element which is set up to receive messages and to exchange the addresses of received messages in such a way that addresses of one type of address are exchanged for addresses of another type of address. Address translators thus enable a subscriber who has a communication terminal that only masters a first type of address to send messages to other communication terminals, which dominate only the other type of address or another type of address. During data packet transmission via a communication terminal serving as an address transmitter, all the data terminals transmit data packets to the (compatible) addresses communicated to them during the connection during the connection, for example IP addresses, where a communication terminal acting as an address converter is the recipient of these data packets, which is the corresponding one Exchanges (for example, IPv4 addresses with IPv6 addresses and vice versa) makes and transmits the data packets to the respective receiving (lying for example in each other IP protocol area) data terminals. With the method according to the invention, it is possible, for example, to undertake a transparent data transmission between IPv4-capable and ΙΡνβ-compliant data terminals.

According to a preferred embodiment of the present invention, it is provided that the address conversion takes place in such a way that messages of a first network element are redirected to a second network element or a second network element to a first network element via a communication terminal functioning as an address converter, wherein addresses of the first Address type in addresses of the second address type or vice versa are exchanged. This is particularly preferably done in such a way that the address part of a communication terminal functioning as an address converter is removed from the receiving message and exchanged for an address part of another type of address, that is to say replaced by it.

The communication terminal functioning as an address converter preferably operates in parallel both as an address converter and as a communication terminal. This is one Such communication terminal preferably with appropriate address translation or an address translation enabling or supporting resources equipped, for example, with a memory device for addresses, a comparison device for comparing addresses, or with other facilities. Some of these devices are already present in a communication terminal, which supports addresses more than a single address type, so are used according to the invention only in another way, namely for address translation. An example of this is any device of such a communication terminal that supports the processing of addresses of more than one type of address. For example, if addresses of a second address type are longer than addresses of a first address type in the sense that addresses of the second address type comprise a larger number of bits than addresses of a first address type, then the memory devices and processing means for addresses in such communication terminals are adapted to this situation. For example, IPv6 addresses are 128 bits long, whereas IPv4 addresses are only 32 bits long.

According to a further preferred embodiment of the invention, the features of which can also be combined with features of other embodiments, a method is provided in which at least a third network element, the switching states of at least one communication element acting as an address converter are known in the computer network for address translation able and ready communication terminal searches and forwards messages for address translation to this communication terminal. Preferably, this third network element, the call processing States of at least one acting as an address converter communication terminal are known to a switching-active network element, for example, a so-called switch or a so-called router, the preferably switching states of a plurality or even a plurality of communication terminals are known, and preferably preferably known which the managed or operated by him communication terminals can act as an address translator. Preference ^¬ as looking out, this third network element to the plurality of communication terminals known to him a suitable communication terminal which can act as an address translator and is ready, the readiness is apparent in particular from the resource utilization of the communication terminal.

According to a further preferred embodiment of the invention, the features of which can also be combined with features of other embodiments of the invention, a method is provided in which in the search for a communication terminal capable of addressing information about the availability of resources required for the address conversion at least one as an address converter acting communication terminal are taken into account.

According to a further preferred embodiment of the invention, the features of which can also be combined with features of other embodiments, it is provided that an address conversion by a communication terminal takes place only or only if at least one dedicated address converter in the computer network reaches its capacity limit. These embodiments have the advantage that the resources required for address translation higen communication terminals are only then occupied, if necessary, which is usually associated with the advantage that the better speed of operation of dedicated address translator can be used for faster address translation.

The invention further provides a communication terminal in a computer network in which two different types of addresses are used, wherein at least a first network element exclusively a first type of address, at least a second network element exclusively a second type of address and at least a third network element uses both types of addresses, and wherein the communication terminal such a third network element is arranged, which is in addition to its function as a communication terminal also perform a function as an address converter with respect to messages for which this communication terminal is neither the original sender, nor a final recipient.

According to a preferred embodiment of the invention, a communication terminal is provided which is adapted to the address translation for messages of a first network element to a second network element or a second network element to a first network element, which are redirected via this acting as an address converter communication terminal, addresses the first Address type in addresses of the second address type or vice versa are exchanged.

According to a further preferred embodiment of the invention, whose features can also be combined with features of other embodiments, the communication is Onsendgerät set up to provide information about the availability of its necessary for address translation resources at least one other network element, preferably on request.

According to a further preferred embodiment of the dung OF INVENTION ^¬ whose features may be combined with features of other embodiments, the communication terminal to a device which recognizes messages that were sent to this communication terminal to the address translation or.

According to a further preferred embodiment of the invention, whose features can also be combined with features of other embodiments, the communication terminal has a device for detecting messages that have been or are routed to this communication terminal for address translation, this device being the address of each of this communication terminal Received message with the address of this communication terminal compares.

According to a further preferred embodiment of the invention, the features of which can also be combined with features of other embodiments, the communication terminal has a device for address conversion, which is set up such that the address of each message received by this communication terminal that does not match the address of this communication terminal is replaced by an address of the first or the second address type, if the address of the received message is an address of the second or the first type of address. According to a further preferred embodiment of the invention, the features of which can also be combined with features of other embodiments, the communication terminal is set up to send a received message whose address has been replaced by an address of the other address type with this address in the computer network.

In the following, the invention will be described in more detail with reference to preferred embodiment and with reference to figures.

It shows

FIG. 1 schematically shows a first embodiment of the invention;

FIG. Figure 2 schematically shows a second embodiment of the invention;

FIG. 3 schematically shows a third embodiment of the invention and

FIG. 4 schematically shows a fourth embodiment of the invention.

The embodiments shown in the figures invariably show methods for addressing messages in a computer network 1, 2, 3, which consists of subnets 1, 2, 3, in which different types of addresses, such as IPv4 addresses and ΙΡνβ addresses are used, wherein subnet 1 exclusively a first type of address, in subnet 3 only a second ad- and in the subnet 2 both types of addresses are used side by side. The network elements 4, 5, 6, 7, 8 of the subnet 1 dominate only addresses of a first type of address, the network elements 14, 15, 16, 17, 18 dominate only addresses a second address type and the network elements 9, 10, 11, 12, 13th master addresses of both types of addresses. Subnets 1, 2, and 3 need not be physically separate or otherwise physically separate subnets. Preferably, the subnets 1, 2, 3 form an otherwise uniform computer network in which network elements of different types are located side by side, which dominate either only a first type of address, only a second type of address or both types of addresses.

The invention is not limited to the case that only two kinds of addresses are used side by side in a computer network. The invention is equally applicable when three or more different types of addresses are used side by side in a computer network.

The FIG. 1 shows an exemplary embodiment in which a communication connection between a network element 8, for example a communication terminal 8 and a network element 16, for example a communication terminal 16, is to be established via a network element 10, for example via a switch 10, wherein the network element 8 only addresses the first Addresses the type of address and wherein the network element 16 dominates only addresses of the second type of address, and wherein the network element 10 controls both types of addresses. The network element 10 now recognizes that a direct communication Onsverbindung between the network elements 8 and 16 due to the different types of addresses, which use these two network elements exclusively, can not easily come about. The network element 10 now chooses in the in the FIG. In the embodiment shown in FIG. 1, the communication terminal 9, which is capable of address conversion and ready, prepares it to carry out an address conversion between the network elements 8 and 16. For this purpose, the network element 10 causes the network element 8 to send the messages destined for the network element 16 to the communication terminal 9, the network element 8 using addresses of the first address type which are easily mastered by the communication terminal 9. The communication terminal 9 replaces the addresses of the first type of address in the messages received by the network element 8 by addresses of the second type of address which address the network element 16 which is actually designated as the recipient of the messages and which only controls addresses of the second type of address. The communication terminal 9 then forwards the messages changed in this way to the network element 16 as intended.

In the case of FIG. 2, the subnet 1 has its own switch 6, which only controls addresses of the first type of address. Similarly, the subnet 3 has a switch 14 which exclusively controls addresses of the second type of address. The connection between the communication terminals 8 and 16 takes place in this case via the switches 6 and 14 of the subnets 1 and 3. These tell the switch 10 of the subnet 3, which controls both types of address, the connection request with, whereupon this switch 10 in similar to that in FIG. 1 embodiment, the connection with the aid of acting as an address converter communication terminal 9 between the communication terminals 8 and 16 builds.

Another in the FIG. 3 embodiment, it is assumed that a dedicated, preferably central address converter 19 is present between the subnets 1 and 3. Assuming, for example, that this dedicated address translator can serve a hundred simultaneous connections and the demand now increases to one hundred and ten connections, a fundamental possibility would be to acquire another dedicated address translator, which in this example would result in the unnecessary capacity of two hundred connections associated with corresponding costs. The invention provides in the in FIG. 3 embodiment now, to realize the ten additionally required connections via acting as an address converter communication terminals of the subnet 2, which would be no or only small additional costs.

The communication terminals capable of address translation according to the present invention are preferably implemented as so-called "dual stack" devices, wherein these devices are basically enabled to decide for themselves, for example depending on the respective communication partner, which address types, for example IPv4 or IPv6, The most common mode of operation of such devices, where the addresses of both IP versions are configured and usable, is called Dual-IP, so a network consisting entirely of devices in dual-IP mode is called a dual-IP network. Since dual-IP-powered devices can communicate with both IPv4 and ΙΡνβ network partners, such devices can generally act as address translators if set up.

In the case of a VVoiP scenario carried out, for example, according to the Session Initiation Protocol (SIP), typically the already existing dual IP-operated switching node (IP softswitch) would assume an additional management function, namely that of a resource broker.

In the switch, the call processing states (in the simplest case: "free" / "in use") of the devices controlled by it are known. If a payload connection between communication terminals with different types of addresses is to be routed via an address converter, the resource broker would preferably search for an appropriate, for example, a free communication terminal which can act as an address converter and is ready for it, and the payload connection for address conversion via this Conduct communication terminal. If a communication terminal capable of address conversion is otherwise required, for example, by its communication subscriber for telephoning and if its resources do not permit the simultaneous execution of both tasks, the payload data connection is preferably routed dynamically via another communication device which is capable of address translation and can be instructed to do so , The likelihood of such a dynamic rerouting of a connection with address translation can preferably be reduced thereby. the, that in the selection of the communication terminal used for communication terminal certain automatically collected statistics are used, for example, the usual ^¬ working hours of the communication participants who use these communication terminals or statistics on the call frequency based on the time of day or the day of the week or the like.

In FIG. 4 is the dual function of FIG. 1, 2, 3 shown communication terminal 9, which indeed so ^¬ probably works as a communication ^terminal and as ^{Adressenumset ¬} zer, has been emphasized by a representation as a double device with the two parts 9.1 and 9.2. The part 9.1, the classical terminal function - symbolized by the receiver - is, in the example, a call ( "call") is initiated or received, which is the case ^¬ play a connection to the communication terminal 11 ge ^¬ shows the second with 9.2. The designated part of the device maintains a connection independent of the part 9.1, which is only routed through for the purpose of the address translation by the device 9, more precisely through its part 9.2 In this context, for the sake of linguistic simplicity, the "device parts" 9.1 or 9.2, this is not intended to mean that a communication terminal 9, which can perform the function of an address converter, necessarily consists of two physically separate parts 9.1 and 9.2. This refers to an at least logical or functional division in which, however, common resources can be shared by both "parts", provided that this sharing of resources does not interfere with the two different functions. In FIGS. 1, 2, 3 and 4 dashed lines indicate control or signaling operations and solid lines with arrows, user data connections to be established or established. The address translation function of the participating communication terminals is preferably controlled by a network element which acts as a resource broker. The invention is also associated with the advantage that already existing but currently unused resources in communication ^terminals that can be used for address conversion, for example, between IPv4 and IPv6 addresses, are actually used by the invention and thus a currently pressing problem of Internet is solved in an efficient manner by the invention.

* * *

Claims

claims

1. A method for addressing messages in a computer network, in which two different types of addresses are used, wherein at least a first network element (4, 5, 6, 7, 8) only a first address art, at least one second network element (14, 15 , 16, 17, 18) exclusively uses a second type of address and at least one third network element (9, 10, 11, 12, 13) uses both types of addresses,

characterized,

in that at least a third network element (9) is a communication terminal which, in addition to its function as a communication terminal, also performs a function as an address converter with respect to messages for which this communication terminal is neither the original sender nor a final receiver.

2. The method according to claim 1, characterized in that the address conversion takes place in such a way that messages of a first network element to a second network element or a second network element to a first network element via an acting as an address converter communication terminal (9) are redirected, wherein Addresses of the first address type in addresses of the second address type or vice versa to be exchanged.

3. The method according to any one of the preceding claims, characterized in that at least one third network element (10), the switching states of at least one acting as an address converter communication Terminal are known, searches in the computer network for an address translation capable and ready communication terminal and forwards messages for address translation to this communication terminal.

4. The method according to claim 3, characterized in that in the search for a communication capable of address communication terminal information about the availability of resources required for the address conversion of at least one acting as an address converter communication terminal are taken into account.

5. The method according to any one of the preceding claims, characterized in that an address conversion by a communication terminal only or only then takes place when at least one dedicated address converter (19) in the computer network reaches its capacity limit.

6. Communication terminal in a computer network in which two different types of addresses are used, wherein at least a first network element uses only a first type of address, at least a second network element exclusively a second type of address and at least a third network element both types of addresses, characterized

in that the communication terminal is such a third network element which is set up, in addition to its function as communication terminal, also to perform a function as an address converter with respect to messages for which this communication terminal is neither the original sender nor a final receiver.

7. Communication terminal according to claim 6, characterized in that the communication terminal is adapted to the address translation for messages of a first network element to a second network element or a second network element to a first network element, which are redirected via this acting as an address converter communication terminal addresses of first address type in addresses of the second address type or vice versa.

8. Communication terminal according to one of claims 6 or 7, characterized in that the communication terminal is adapted to provide information about the availability of its resources necessary for the address conversion at least one other network element, preferably on request.

9. Communication terminal according to one of claims 6 or 7, characterized in that the communication terminal has a device which detects messages that have been routed to this communication terminal for address translation or will.

10. Communication terminal according to claim 9 with a device for detecting messages that have been or are routed to this communication terminal for address conversion, characterized in that this device compares the address of each received message from this communication terminal with the address of this Kommunikationsendge- device.

11. Communication terminal according to claim 10, characterized by a device for address conversion which is directed that the address of each message received from this communication terminal, which does not match the address of this communication terminal, is replaced by an address of the first and the second address, if the address of the received message by an address of second or the first Ad ^¬ ressenart acts.

12. Communication terminal according to claim 11, character- ized in that the communication terminal is adapted to send a received message whose address has been replaced by an address of the other address type, with this address in the computer network.