SE521089C2 - Telecommunication system and method for routing calls in a telecommunication system - Google Patents

Abstract

The present invention relates to a Telecommunication System for routing a call from a first subscriber via an originating circuit switch over an IP network via a destination circuit switch to a second subscriber. Today address translation tables for translating standardised addresses used in ISDN and PSTN into IP addresses have to be stored in the IP Telephony Gateways. The administrators of the IP Telephony Gateways have to keep track of the number plans of all the different circuit switched networks. When the network of interconnected IP Telephony Gateways grows the required manual administration of the current solutions increases significantly. This problem is solved by means of a Telecommunication System wherein the local circuit switches store the IP addresses to its associated Gateways.

Description

20 25 30 521 089 [110942 halc 00-01-27 2 mast the destination of the call where the call is converted back to a circuit-switched call and routed in the circuit-switched network to the final destination. In this way, the main part of the transmission path will be located via the Internet instead of the circuit-switched network, especially for international calls.

This is a very advantageous method, but there are limitations. The Internet uses IP addresses for addressing and IP and Internet protocols are used to route traffic. The circuit-switched network, on the other hand, uses standardized E.l64 or E.2l2 addresses for addresses such as E.l63 (eg telephone numbers). To route calls in (ISDN User Part) and TUP for the common channel signaling circuit-switched network, ISUP (Telephone User Part) system no. 7 and sometimes older signaling schedules are used, e.g. R2.

These addressing and routing methods for the Internet and completely different and. there is no harmonization or integration of 'these two. the circuit-switched network is More specifically, there is no connection between the standardized circuit-switched addresses and IP addresses.

This means that there is no obvious automatic way to translate standardized addresses used in ISDN and PSTN into IP addresses. an IP gateway itself must be able to analyze the received This in turn means standardized ISDN / PSTN destination addresses. and from this analysis extract the correct address of the IP telephony gateway associated with the end receiver. This works well, but only as long as the interconnected IP telephony gateways are relatively few. When e.g. only if there is an IP telephony gateway in each country, the analysis of the standardized addresses is very easy. A simple program and a mapping table are enough to translate the country code of the telephone number into an IP address for the gateway located in the country in question. 10 15 20 25 30 521 089 P10942 hale 00 ~ 01 ~ 27 3 The document WO9836543 shows a gateway system for processing calls over the Internet. The system uses a distributed database on the Internet to translate the dialed number of a telephone call into a priority list of preferred gateways for that call.

However, as the number of IP telephony gateways increases in number, this solution presents economies of scale. It will no longer be enough to check only the country code. In addition, the IP telephony gateway must know each recipient's internal numbering plan in order to be able to route the call to it. This will create very large tables for mapping addresses, eventually which will not only complicate the analysis of the standardized IP telephony gateway. . will so the addresses but will also be very difficult to maintain. Since the exchange of address information does not take place automatically between. the circuit-switched network and the Internet, the mapping tables must be maintained manually. This means not only the administration of a large amount of data but also keeping track of changes in the numbering plans for all relevant networked network operators in all the countries concerned.

The tables must be IP telephony- also updated when a new gateway is installed or when old IP telephony gateways are taken out of operation. fax traffic where the IP-based telephony and IP- and it is obvious that current In a scenario popularity increases large volumes based telephone / fax traffic, solutions for addressing and. routing are not economically well suited. A more automatic solution will be needed. Such a solution is what the present invention proposes.

SUMMARY OF THE INVENTION The present invention addresses the problem of lack of connection between the addressing system of the circuit-switched network. and the IP addressing system when a call is routed from a first subscriber via an output exchange (by output exchange is meant in this document the appropriate exchange which is closest to the calling subscriber, trans. .) through an IP network in this document the appropriate exchange closest to the one dialed on via an input exchange (by input exchange is meant the subscriber, trans. note) to a second subscriber.

Today, addressing tables, for translating addresses from circuit-switched network addresses to IP addresses, must be stored in IP telephony gateways or associated databases. The administrators of IP telephony gateways and / or databases must keep up to date. the numbering plans for all different circuit-switched networks. As the network of interconnected IP telephony gateways grows, the necessary manual administration of current solutions increases significantly.

The object of the present invention is thus, when the call is routed, to obtain the nearest input switch of the nearest input exchange or the IP address of the currently best IP telephony gateway by using the inherent routing capabilities of the circuit-switched network.

The above-mentioned problems are solved by a telecommunication system in which the local exchanges store the IP addresses of their associated gateways. The following scenario for directing the call describes the idea of the invention.

A first subscriber dials a second subscriber's number. The number is analyzed by the output gear and adjacent gears along the transmission path up to the input gear. Through this distributed analysis, the input switch is found. The output gear. then interrogate the input switch on its associated IP telephony gateway.

An associate. The IP telephony gateway can be the one that. is closest to or currently the best IP telephony gateway.

The IP address is returned to the output exchange and transmitted to its associated IP telephony gateway. The call can then be routed through the IP network to the other subscriber via the IP telephony gateway associated with the input exchange and further via one or more subsequent exchanges. 10 15 20 25 30 521 089 pmm: ax oom-zv 5 En. advantage of the present invention is that no address translation capability is required by the IP telephony gateways or their associated databases. that the telephony gateway administrators do not need to track and Another advantage of the present invention is the IP update numbering plans for all the different circuit-switched networks.

Another advantage of the present invention is that the manual administration of the addresses is reduced to a minimum as well. for a network Ined a fast number of growing IP telephony gateways.

Yet another. The advantage of the present invention is that the circuit-switched networks that it offers to traditional operators become competitive as they diversify their operations into the IP telephony and fax business area.

A further field of application of the present invention will become apparent from the detailed description below. It is to be understood, however, that specific examples in connection with the detailed description of preferred embodiments are purely illustrative, as a variety of changes and modifications fall within the scope and spirit of the invention, as will be apparent to one skilled in the art.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 illustrates the telecommunication system according to the invention.

Fig. Shows a flow chart for call routing.

Fig. Shows a signaling sequence for an IP network information.

Fig. 4 shows a signaling sequence when an IP address is investigated and returned. Fig. 5 shows a signaling sequence when an IP address is investigated and returned.

Fig. 6 shows a signaling sequence when an IP address is investigated and returned.

Fig. 7 shows a signaling sequence when an IP address is investigated and returned. Fig. 8 shows a signaling sequence when an IP address is investigated and returned.

Fig. 9 shows a signaling sequence when an IP address is investigated and returned in a tunnel.

Fig. 10 shows a signaling sequence when an IP address is investigated and returned.

Fig. 11 shows a signaling sequence for one. transmission of an IP address.

Fig. 12 shows a signaling sequence for one. transmission of an IP address in a tunnel.

Fig. 13 shows a signaling sequence for transmitting an IP address.

Fig. 14 shows a signaling sequence for the routing of the call in the case where the circuit-switched network is a PSTN.

Fig. 15 shows a signaling sequence for the routing of the call in the case where the circuit-switched network is an ISDN.

DESCRIPTION OF PREFERRED EMBODIMENTS Fig. 1 shows a preferred embodiment of the telecommunication system 101 in which a call can be routed from a first subscriber A in a circuit-switched network 103, through an IP network 102 to a second subscriber B in the circuit-switched network. the network 103.

The subscriber A has a fax 106 or a telephone 107 connected in it can be an ISDN or a PSTN. The subscriber B has a facsimile 108 or a telephone 109 connected to a network 103 which is connected in circuit to an output switch 104, e.g. 10 15 20 25 30 521 089 1310942 slippery 00-01-27 7-speed switch 105 i. The circuit-switched network 103. The gears 104 and 105 are connected to each other possibly by one or more intermediate gears 116.

The 102 has 110, the IP address 112 and the IP telephony gateway 113, the circuit-switched network 103 is connected to the IP network via the IP gateways 110 and 113, respectively, each IP gateway 112 115. which is associated with the output switch 104, an IP address and the IP telephony gateway have a first one which is associate- The output switch 104 is connected to its associated IP gateway, row with the input switch 105, has a second IP address 115.

The IP telephony gateway 110 for the outgoing call, possibly The input exchange 105 IP telephony via one or more transit exchanges 111. is connected to its associated IP gateway, the gateway 113 for the incoming call, possibly via one or more transit exchanges 114 .

The local exchanges that can receive and handle incoming calls store the IP address of their associated IP telephony gateway.

The exchange 104 thus stores the IP address 112 of its associated IP telephony gateway 110, and the exchange. 105 stores the IP address 115 of its associated IP telephony gateway (s) 113. It is for IP telephony gateways for operational security reasons. It is currently also possible to store alternative IP addresses, there are normally fewer IP telephony gateways than switches, but in the future the opposite may be a fact.

It is also possible to place the exchange and its associated IP telephony gateway in one and the same node. The exchange 104 and its associated IP telephony gateway 110 would then be located in one and the same node and the exchange 105 and its associated IP and the same telephony gateway 113 would be located in the node.

An additional possibility is to place the transit exchange and its associated IP telephony gateway in one and the same node. 10 15 20 25 521 osau 1310942 hah: 0001-27 8 The transit exchange 111 and its associated telephony gateway 110 would then be located in one and the same node and the transit exchange 114 and its associated IP telephony gateway 113 would be located in the same node.

Fig. 2 shows a flow chart of a possible scenario for an through an IP network 102 to a routing of calls from a first subscriber A in circuit-switched network 103, second subscriber B in the circuit-switched network 103. The second subscriber B has a subscriber number B .

The call routing method includes the following steps: 201 A user A starts by dialing Bz's subscriber number and 202 indicates that the IP network 102 can be used for the call in question. 203 Bz's numbers are analyzed in part by the output exchange 104 to initiate the establishment of the call and in part by intermediate exchanges 116 along the transmission path to identify the input exchange 105. 204 The output exchange 104 interrogates the input exchange 105 regarding an IP address 113. routed through. the circuit-switched network 103, 209. 115 for its associated IP telephony gateway If such an IP address is missing, the call will step 205 The input exchange returns the requested IP address 115 to the output exchange 104. 206 to the output exchange IP address and the call is transmitted 104 associated IP telephony gateway 110, 207 the call is routed through the IP network 102, 10 15 20 25 30 521 089 P10942 hale 00-01-27 9 208 to the subscriber B via the IP telephony gateway ll3 associate-105 IP- address 115 and Bz's number. row with the input switch using different embodiments for the different steps of the routing method will now be described in more detail followed by a description of the preferred embodiment for the whole method.

An easy way to indicate to the network that an IP network can be used for a particular call in step 202 is to dial a predetermined access code before the actual telephone number. Such an access code can e.g. be an arbitrary number sequence followed by a square sign (#) It can also be yet. simpler, followed by B's real subscriber number. for example to just dial the square sign (#) before dialing the real number.

Another option, in the case of a PSTN or an ISDN, is to specify that the IP network 102 can normally be used for all calls. This can be done implicitly through subscriber data in local exchange 104. If subscriber A does not want to use the IP network for a specific call, he can dial a certain access code before dialing Bz's subscriber number.

An alternative for the case of ISDN is to explicitly state the IP network in the "SETUP" message from subscriber A as described. There are several ways to do this, e.g. by using a special value in the information view in Fig. 3. the element "Transit Network Selection information element".

Transit Network Selection is information sent in the initial address message indicating that the requested transmission network is to be used for the call as specified in Chapter 2.144 of ITU Recommendation Q.762. Another way is to use (International Telecommunication Union) a special value in the information element "Network Specific information element". Network Specific Facilities is service related. information. as. transmitted transparently in any direction between the local exchange and the identified network providing the service. The information is important for both the network as specified in Chapter 2.92 of the ITU's recommended user and the identified dation Q.762. This information element is used to select which ones. network devices to be invoked, e.g. choice of backbone network. Another way is to use a new parameter or a spare bit in the information element "Bearer Ca- A further way is to so-called in information eleability information element". use one of the reserved parameter values in a "User Information Layer three parameter" element Bearer Capability information element.

In Fig. 4, step 204, the interrogation of the IP address can be done by the "ISUP" - (ISDN User Part) message "IAM" (Initial Address Message) by using the common channel signaling in case the circuit-switched network 103 is an IAM is a message sent to System # 7, ISDN. to initiate the use of an output circuit and to override the forward direction to enter numbers and. other information combined. with. the routing and handling of a call as specified in Chapter 1.32 of ITU Recommendation Q.762.

IAM supports the use of the optional "Remote Operation" parameter, which is used to specify the invocation of an additional service identified by an operation value, and also to carry the result or error indications depending on operation chapter 2.128 of the output. specified in ITU Recommendation Q.762.

IAM also supports the use of the optional "Generic Notification" parameter, which is information sent in any direction intended to provide information to a user regarding additional services as specified in Chapter 2.53 of ITU Recommendation Q.762. The switch for the incoming call 105 can, after determining from the Generic Notification parameter, that the call will not be routed “RE L” through. the circuit-switched network 103, return a 10 15 20 25 30 521 089 mom mic oom-zv 1 1 (Release message) in step 205 which is a message sent in some direction to indicate that the circuit is being released for a reason provided ( cause) and is ready to enter sleep mode upon receipt of the complete disconnection message. If the call is diverted or is about to be redirected, the appropriate indicator is carried in the message together with the redirection address and the redirection address specified as in Chapter 1.37 of ITU Recommendation "Q.762.

REL supports the use of the "User-to-User Information" parameter to carry the IP address 115. This parameter is normally used for information generated. by a user and is transmitted transparently through intermediate switches and networks between the output and input switches as specified in Chapter 2.155 of ITU Recommendation Q.762.

Fig. 5 and Fig. 6 show that the input switch 105 can also return the IP address according to step 205 with an “ASM” (Address Complete Message) which is a message sent in the reverse direction and which indicates that all address signals necessary to route the call to the called party has been received, as specified in Chapter 1.1 of ITU Recommendation Q.762. Again, ACM supports the use of the 'User-to-User Information' and Remote Operations parameters.

If the request has been sent in a Remote Operations parameter in the IAM, the parameter in the ACM must. the address is returned in a Remote Operations- The output switch 104 then responds with a REL to which the input switch 105 responds with an RLC (Release Comp- See Fig. 5. direction in response to a received shutdown message, el- a lete Message). An RLC message is sent in. Someone smiles appropriately at the circuit reset message, when! ¿The circuit in question has been put into sleep mode as specified in Chapter 1.38 of ITU Recommendation Q.762. The output switch 104 may alternatively transmit an RLC in response to the ACM. See Fig. 6.

Fig. 7 shows other options for step 204. If the circuit-switched network 103 is an ISDN, it is possible to execute an ISUP message, a specifically designed optional parameter or the interrogation via a specially designed optional parameter value in an ISUP message .

Other options for step 205, if the circuit-switched network 103 is an ISDN, are to return the IP address 115 by means of a specifically constructed ISUP message or by means of a specifically constructed optional parameter in an ISUP message, also shown in Fig. 7.

When a new message or parameter is introduced or a parameter already used for other purposes is used in step 204 or 205, an instruction indicator must be included that instructs the intermediate gear (s) 116 to forward. the message or "parameter even if it is not recognized", see Fig. 8. The instruction indicators are included in the two parameters "Message Compatibility Information parameter" and "Compatibility Information parameter".

The parameters. Message Compatibility Information Parameters concern information sent in any direction and indicate how a switch should react if this message is not recognized as specified in Chapter 2.79 of ITU Recommendation Q.762. The parameter Message Compatibility Information Parameter must have Set to "PASS ON".

The Discard Message Indicator is information sent to the "Discard Message Indicator" to inform another node whether or not to discard the related message, due to unrecognized compatibility reasons such as. specified in Chapter 2.40 of ITU Recommendation Q.762. The Discard Message Indicator 10 15 20 25 30 521 089 Pwwzmkwßr fi 13 is also present in the “Parameter Compatibility Information Parameter” parameter.

In the case of a specifically designed optional parameter or a specifically designed optional parameter value, the parameter Parameter Compatibility Information Parameter shall be used which relates to a part of information sent in some direction indicating how a gear should react if the parameter is not recognized as specified in Chapter 2.105 of ITU Recommendation Q.762. The Discard Parameter Indicator indicator should be set to PASS ON in the Parameter Compatibility In- Indicator parameter is information sent to inform another node to formation. Parameter. The indicator. Discard Parameters discard the related parameter, due to unrecognized compatibility reasons as specified in Chapter 2.41 of ITU Recommendation Q.762.

Fig. 9 shows an alternative to the above-mentioned instruction indicators. In the case of intermediate switches 116 and in the case of ISDN, it is possible to use ISUP's 'AHW' (Application Transport Mechanism) to create a tunnel 117 between the output switch 104 and the input switch 105 via the intermediate switch (s) 116 APM is an ISUP extension that provides a. carrier for application-specific signaling ITU recommendation ITU 'Q.765.

This carrier can be imagined as a "tunnel", since the ring, as specified in the information transmitted between APM's user applications, is transparent to the intermediate nodes.

If the circuit-switched network 103 is a PSTN, the interrogation according to step 204 can be performed by means of a spare bit in "TUP's" Part) "IAM" (Initial Address Message), such as. described in Initial Address Message 10.

Message is a type of message sent in the direction It (Telephone User fig. At the establishment of the call. Contains' address information and other information concerning the routing and handling of the call, as specified in Chapter 1.1.1 of the ITU's recommendation 10 15 20 25 It is also possible to specifically construct the TUP message or to construct a TUP message for the interrogation. return the IP address 115 in step 205 and in the case of the PSTN, in which case it is possible to specifically construct a TUP message.

Fig. 11 describes an embodiment for transmitting the second IP address 115 from the output exchange 104 to the IP telephony stage 206. The transmission is performed by means of a specifically designed ISUP (ISDN User Part) or TUP division. gateway 110, associated with the output switch. 104, (Telephone User Part) with- The transmission according to step 206 can be performed by means of internal communication means if the IP telephony gateway 110 is located in the same node as. either its associated gear 104 or the transit gear 111.

In the same step 206, there are other options if the circuit-switched network is an ISDN. One, 12, transmitting the second IP address 115 transparently by means of the shown in Fig. Is that a specifically constructed tunnel 118 between the exchange 104 and the appropriate IP telephony gateway 110 by means of the ISUP mechanism "APM" (Application Transport Mechanism).

Three other alternatives are to perform the transmission using ISUP by using IAMs (Initial Address Message) parameters “Generic Number Parameter” or “Generic Reference Parameter” or “User-to-User Information Parameter”, see fig. 13.

The same step 206 can be performed by means of a specific design message IAM if the circuit-switched network erad parameter in TUP (Telephone User Part) (Initial Address Message), 103 is a PSTN. Preferred embodiments of the complete method came for PSTN and one for ISDN, the steps taken from the above description. more now described, with the various First case with PSTN, 14. Subscriber A dials 201 subscriber B's number. Subscriber data in exchange 104 indicates, as shown in Fig. 202, that an IP network should be used as an implicit implicit alternative. This can be canceled by subscriber A through the use of a special access code. The Bz number is partially analyzed 203 by the output exchange 104 to initiate the establishment of the call and is partially analyzed by intermediate exchanges 116 along the transmission path to identify the input exchange 105. The output exchange 104 then interrogates the input exchange 105 onx the IP address. 115 for its associated IP telephony gateway 113 by using one or more spare bits in the IAM message. After returning 205 of the IP address 115 in a TUP message, 206 the IP address 115 i. A specifically designed parameter j. The IAM specifically designed is transmitted to the IP telephony gateway. 110 associated. with. the output switch 104. The call is then routed 207 through the IP network 102 to the telephony gateway. 102 associated. with the input switch 105 using the IP address 115 and is then routed 208 to the subscriber B in the PSTN network 103 by means of the input switch 105 on the receiving side using the Bz number.

The preferred embodiment in the case of ISDN is shown in Fig. 15. Subscriber A 201 Bzs The SETUP message indicates 202 the use of the IP network for dialing subscriber numbers. through the Transit Network Selection information element. The Bz number is analyzed 203 partly by the output switch 104 to start routing the call and partly by the intermediate switch 116 along the transmission path to identify the input switch 105. The output switch 104 interrogates 204 then the input switch 105 about the IP address 115 of its association 113 to IAM message parameter Remote Operations parameter. After the row IP telephony gateway by using the IP address 115 returned in the ACM message parameter Remote Operations parameter 206 the IP address 115 is transmitted by means of a unused parameter value for IAMs parameter Generic Number parameter to the IP telephony gateway 110 associated with the output switch 104. The call is then routed 207 through the IP network 102 and then routed 208 to the subscriber B in the PSTN network l03 via the input switch l05 by using Bz's number.

As a variant, further of the embodiments, the switch may return one, two or more IP addresses to one, two or more corresponding IP telephony gateways to provide. redundancy. from the output switch to its associated IP telephony gateway.

All IP addresses are also transmitted If more than one IP address is returned, the first in the list (for this specific call) belongs to the preferred IP telephony gateway associated with the input exchange. However, if the preferred IP telephony gateway associated with the input switch is currently not accessible from the IP telephony gateway associated with the output switch, or for some reason out of order, the second IP address in the list is used. If no success is achieved with the other IP address, the next in the list is tried, until the call is successfully routed through the IP network to associated with or an IP telephony gateway input switch until the list ends.

The embodiments described above serve only an illustrative purpose

Claims (48)

10 1 2 N) Lh 5 0 521 089 ll PATENT REQUIREMENTS A telecommunication system (101) for routing a call from a first subscriber (A) through an IP network (102) to a second subscriber (B), the telecommunication system (101) comprising: a circuit-switched network (103) including a local output switch (104) and a local input switch (105), (104) said local output switch is connected to a first subscriber line (106 and 107, respectively) for the first subscriber (A), said local input switch (105) is connected to a second subscriber line ( 108 and 109, respectively) for the second subscriber (B), said local output switch (104) is associated with an IP telephony gateway (110), said IP telephony gateway (110) has a first IP address (112), said local input switch (105) is associated with an IP telephony gateway (113), said IP telephony gateway (113) has a second IP address (115), said IP gateways (110 and 113, respectively) have * each and an interface to the IP network (102), (104 105) stores an IP address for its respective associated The IP (110 113) first subscriber is characterized in that each of the exchanges and telephony gateways, respectively, for directing the call from the (A) via the local 10 15 20 25 521 089 | 8 (102) further via the other subscriber (B). (104) the local input switch (105) the output switch through the IP network Telecommunication systems according to claim 1, characterized in that they are located in one and the same (110 that the exchanges (104 and 105, respectively) node as their respective associated IP telephony gateways and 113, respectively). Telecommunication system according to claim 1, characterized in that (103) between the local output switch the circuit-switched network includes one or more (116) (104) and the local input switch (105). intermediate gears Telecommunication system according to claim 3, characterized in that at least one of the two IP telephony gateways (110 and 113, respectively) is located in one and the same node as its associated transit axis (111, 114). A method of routing a call in a telecommunication system (101) according to any one of claims 1-4 from a first subscriber (A) via a local output exchange (104) through an IP network (102) further via a local input exchange (105). ) to a second subscriber (B), characterized by comprising the following steps a) dialing (201) a subscriber number (B); b) indicating (202) that the IP network (102) can be used for the call; c) analyzing (203) the dialed subscriber number (B) to identify the local input switch (105); d) interrogating (204) the local input switch (105) about the second 1P address (115) of the local input switch (105) associated IP telephony gateway (113): 10 15 20 25 30 521 089 IC! e) to return (205) the second IP address. (115) to the local output switch (104); f) transmitting (206) the second IP address (115) to the associated IP telephony gateway (110) of the local output exchange (104) and directing the call to said IP telephony gateway (110); g) directing ( 207) the call to the local input exchange (105) associated with the local input exchange (105), through the IP network (102) using the second IP address (115); h) directing (208) the call to the other subscriber (B) via the local input exchange (105). Method according to claim 5, characterized in that in step b) (202) the IP network (102) to route the call by dialing a predetermined access code before specified can be used for dialing. the subscriber number (B) characterized in that in The method of claim 5, (202) (102) may be used to route the call. step B indicates implicitly, through subscriber data, the IP network Method according to claim 7, characterized in that a certain access code is dialed before the subscriber number (B) is dialed, said access code indicating that this specific call will not be routed through the IP network. Method according to claim 5, characterized in that in step b) (202) it is explicitly stated in a so-called SETUP message from the subscriber (A) that the IP network (102) can be used to route the call, if the circuit-switched network (103) is an ISDN. Method according to claim 9, characterized in that said indication in the so-called The SETUP message is executed by means of a special value in the Transit Network Selection information element. Method according to claim 9, in the so-called The SETUP message is executed by means of a special feature in that said indication value in the information element Network Specific Facilities information element. Method according to claim 9, characterized in that said indication in the so-called The SETUP message is executed using a new parameter in the Bearer Capability information element. Method according to claim 9, characterized in that said indication in the so-called The SETUP message is executed using a spare bit in the Bearer Capability information element. Method according to claim 9, characterized in that said in the so-called SETUP ~ message reserved value for the parameter s.k. entry is performed using a User Information Layer 3 information element Bearer parameter in Capability information element. Method according to claim 5, characterized in that said interrogation in step d) (204) is performed by means of an ISUP (ISDN User Part) message called IAM (Initial Address Message), if the circuit-switched network (103) is a ISDN. Method according to claim 15, characterized in that the interrogation regarding the second IP address is performed by means of the optional IAM parameter Remote Operations parameter. Method according to claim 15, characterized in that the interrogation regarding the second IP address is performed by means of the optional IAM parameter Generic Notification parameter. Method input switch local from according to claim (105) in 15, characterized in that the step d) (204) determines, in the parameter Generic Notification parameter, that the call will not be routed through the circuit-switched network (103 ). Method according to claim 17 or 18, characterized in that the return in step e) (205) is performed by means of a so-called ISUP REL (Release) message using the User-to-User Information parameter. Method according to one of Claims 15 to 18, characterized in that (205) is executed by means of an ACM (Address Complete Message) message. the return in step e) Characterized in that the second IP address Method according to claim 20, is returned by means of the optional ACM parameter User ~ to ~ User Information parameter. Method according to claim 20, characterized in that the second IP address is returned by means of the optional ACM parameter Remote Operations parameter. characterized by that Method according to any one of claims 15-22, the local output switch (104) responds with a REL (Release) message. Method according to one of Claims 15 to 22, characterized in that the local output switch (104) responds with an RLC (Release Complete) message. 25. characterized in that said interrogation in step d) (204) is performed by means of a specifically constructed ISUP (ISDN User Part) if that network (103) is an ISDN. Method according to claim 5, message circuit-switched A method according to any one of claims 5 or 25, characterized by (205) (ISDN User Part) (103) is performed by means of a message if the return in step e) specifically designed ISUP - the circuit-switched network is an ISDN. 10 15 20 25 30 521 089 22 Method according to claim 5, characterized in that said interrogation in step d) (204) is performed by means of a specifically constructed optional parameter in an ISUP (ISDN User Part) message if the circuit-switched network (103) is an ISDN. Method according to any one of claims 5 or 27, characterized in that said return in step e) is performed by means of a specifically constructed parameter in an ISUP (ISDN User Part) if the circuit-switched (103) is a message network ISDN. Method according to claim 5, characterized in that said interrogation in step d) (204) is performed by means of a specifically constructed optional parameter value in an ISUP (ISDN User Part) message if the circuit-switched network (103) is an ISDN. A method according to any one of claims 16, 18, 19, 25, (204) instruction parameter that 27 or 29, further comprises the step of characterized in that step d) instructing the IP plurality includes one forwarding the other if the intermediate switches address request unchanged, there is one or intermediate switches (116). The method of any of claims 26 or 28, characterized in that step e) (205) further comprises the step of including an instruction indicator to instruct the intermediate switches to forward the return of the second IP address (115) unchanged if there is a or several intermediate gears (116). Method according to claim 30 or 31, the case of the specifically constructed ISUP message, PASS ON, characterized in that, in (ISDN User Part), the Discard Message Indicator is set to the Message Compatibility Information parameter. 1 1 0 5 20 25 LA) C) 521 089 23 Method according to claim 30 or 31, the case of a case with an optional parameter value in an ISUP message, characterized in that, in specifically designed optional parameter or setting the indicator Discard Parameter Indicator to PASS ON in the parameter Parameter Compatibility Information parameter. Method according to claim 5, characterized in that in steps d) (204) and e) (205) the ISUP mechanism uses the Application Transport Mechanisn1 (APM) to create a tunnel between the local output switch (104) and the local input switch. (105) via the intermediate switches (116) for transparently transmitting requests and return messages concerning the second IP address, if the circuit-switched network (103) is an ISDN. Method according to claim 5, characterized in that in step d) (204) performing said request by means of a spare bit in the TUP ~ (Telephone User Part) message IAM (Initial Address Message), if the circuit-switched network (103) is a PSTN. Method according to claim 5, characterized in that said interrogation in step d) (204) is performed by means of a specifically constructed optional parameter in the TUP (Telephone User Part) message, if the circuit-switched network (103) is a PSTN. Method according to claim * 5, characterized in that said interrogation according to step d) (204) is performed by means of a specifically constructed TUP (Telephone User Part) message, if the circuit-switched network (103) is a PSTN. The return Method according to any one of claims 35-37, characterized in that according to step e) is performed by means of a specifically designed TUP message. Method according to one of Claims 35 to 37, characterized in that the return according to step e) is performed by means of a specifically constructed parameter in the so-called TUP-ACM (Initial Address Message) message. B) C) 521 089 24 characterized in that said transfer of a Part) Method according to claim 5, f) (206) ISUP message with (ISDN is performed specifically TUP- in the step help constructed User or message (Telephone User Part). Method according to claim 5, characterized in that said transmission in step f) (206) is performed by means of internal communication means if the IP telephony gateways (110 and 113, respectively) together with suitable switches (104, 105) are located in the same node. . 42. characterized in that said transmission in step f) one (111 and 114, respectively) gateways (110 and 113, respectively) are located in the same node. when claim 5, depends on claim 4, (206) communication means, Method according to claim 5, is performed in case and appropriate IP telephony by means of the internal transit exchanges Method according to claim 5, characterized in that said transmission (115) if) (206) a constructed tunnel of the second IP address step takes place by means of specific (104) by means of an ISUP transparent its associated IP ( ISDN User Part) if there is an ISDN between the local output switch and (110) Application Telephony Gateway Mechanism Mechanism, in the circuit-switched network (103). Transport Method according to claim 5, characterized in that said transmission of the second IP address (115) in step f) (206) takes place by means of the ISUP (ISDN User Part) message IAM (Initial Address Message), if the circuit-switched the network (103) is an ISDN. Method according to claim 44, characterized in that the second IP (115) Number parameter. the address is transmitted using the Generic IAM parameter 46. Method according to kr v 44, characterized in that the second IP (115) Reference parameter. the address is transmitted using the IAM parameter Generic 10 521 089 ïy¿;: q zs Method according to claim 44, characterized in that the second IP (115) User Information parameter. the address is transmitted using the IAM parameter User ~ to- Method according to claim 5, characterized in that said transmission of the second IP address (115) (113) in step f) (206) constructed parameter in to said IP telephony gateway takes place TUP ~ (the Telephone message, is a PSTN using a specific Party (IAM) if the circuit-switched User (Initial Address Message) network