WO2007065425A1 - Routing of data of a tc connection between a calling tc terminal and a called cellular terminal via a cellular network or a wlan - Google Patents

Abstract

The invention relates to a method and a telecommunication configuration for routing data of a telecommunication (TC) connection between a calling TC terminal (1) and a called cellular terminal (2) which is equipped with at least one access module (21) to a cellular network (6), a WLAN access module (22) to a wireless LAN (WLAN) (3), a voice-over-IP (VoIP) functionality (23), and means (27) to determine whether or not the cellular terminal (2) is located in a WLAN (3). The inventive method comprises the following steps: it is determined whether the cellular terminal (2) is located in a WLAN (3); the data of a TC connection to the cellular terminal (2) is routed to the cellular terminal (2) via at least one cellular network (6) if the cellular terminal (2) is not located in a WLAN (3); the cellular terminal (2) is logged into the WLAN (3) by means of the WLAN access module (22), and alternative routing of the data of a TC connection to the cellular terminal (2) is provided if the cellular terminal (2) is located in a WLAN (3). Alternative routing encompasses routing of the data as IP data from a TC device (5, 8) to a WLAN (3) router (31) and from there to the cellular terminal (2) via the WLAN (3).

Description

 ROUTES OF DATA FROM A T C CONNECTION BETWEEN A CALLING TK TERMINAL AND A CALLED MOBILE RADIO DEVICE VIA A MOBILE NETWORK OR A WLAN

description

The invention relates to a method for routing data of a telecommunications (TC) connection between a calling TK terminal and a calling mobile terminal, and a telecommunications arrangement for performing the method. The present invention allows inexpensive roaming of a mobile radio subscriber with the aid of WLAN technologies. ^■

Background of the Invention

It is known to pack voice and other data in IP (IP = Internet Protocol) data packets and to transmit them to a mobile radio terminal device via wireless local radio networks, generally referred to as WLAN (WLAN = Wireless Local Area Network). Such a mobile radio terminal is provided with a WLAN device and a VoIP (Voice over IP) functionality, which allow IP packets received via the WLAN to be converted into voice, video or text data and data into IP

Packet data packet fees and send them over the WLAN. In the following, VoIP is not only understood to mean the transmission of voice by means of IP packets, but also the transmission of other data, such as video and text, by means of IP packets which are transmitted in the context of TC connections. The

Sending VoIP data over wireless local radio networks is also referred to as VoWLAN (Voice over WLAN). Plug-in cards for PC notebooks are also known which provide data transmission via GPRS, UMTS and WLAN. If the PC notebook is in a WLAN hotspot it can send and receive data using WLAN technology. If it is outside of a WLMT, it communicates via GPRS or UMTS. Also known are mobile telephones which integrate both a WLAN functionality and a GSM or UMTS functionality. Both networks (WLAN and GSM / UMTS) are used by such mobile phones by roaming between the WLAN and the GSM / UMTS network. Such roaming requires cooperation between the mobile network operator and the WLAN operator. The mobile network operator has complete cost control. Another disadvantage is that not just any WLAN can be used, but only those that provide roaming with a mobile network.

There is a need for communication methods that allow cell phone and WLAN technologies to be combined effectively and subject to minor restrictions.

Object of the invention

Accordingly, the object of the present invention is to provide a method and a telecommunication arrangement for routing data between a calling TC terminal and a called mobile radio terminal, which effectively combine WLAN and mobile radio technologies without the need for between the corresponding networks require roaming.

Summary of the invention

This object is achieved according to the invention by a method with the features of claim 1 and a telecommunications arrangement with the features of claim 18. Preferred and advantageous embodiments of the invention are specified in the subclaims.

The solution according to the invention then provides for a mobile radio terminal to determine whether it is in a WLAN or not. If the mobile radio terminal is not in a WLAN, the data of a TC connection to the mobile radio terminal is routed via at least one mobile radio network to the mobile radio terminal, i.e. there is a normal data transmission to a mobile radio terminal via one or more mobile radio networks coupled via roaming agreements. If, on the other hand, the mobile radio terminal is in a WLAN, the mobile radio registers in the WLAN by means of the WLAN access module and an alternative routing of the data of a TC connection to the mobile radio terminal is provided. This alternative routing comprises routing the data as IP data from a telecommunications device to a router of the WLAN and from there via the WLAN to the mobile radio terminal.

The solution according to the invention enables a mobile radio subscriber or a mobile radio terminal of a mobile radio subscriber, when it is in a WLAN, to receive incoming calls via the IP network and the WLAN instead of via the mobile radio network. Reception via IP and WLAN takes place when the mobile terminal determines that it is in the radio range of a WLAN and has registered in it. When the mobile radio subscriber leaves the WLAN, the mobile radio terminal receives data again via the mobile radio network in which it is registered and authenticated, or via a mobile radio network coupled to it via a roaming agreement. The solution according to the invention avoids the occurrence of roaming charges, which can be considerable in particular in the event that the mobile radio terminal is in a foreign mobile radio network. The solution according to the invention presupposes that the mobile radio terminal has certain functionalities. It must have: an access module to at least one mobile radio network, a WLAM access module to a WLAN, VoIP functionality and means for determining whether the mobile radio terminal is in a WLAN or not. An access module to a mobile radio network is a necessary part of every mobile radio terminal. A WLAN access module is also known in the prior art. Such access modules are commercially available, for example, for PC notebooks. VoIP functionality of a mobile radio terminal is also known: the mobile radio terminal sends out and receives data packets in accordance with the IP standard. Examples of terminal devices with this functionality are commercially available “Wi-Fi handsets”. Means for determining whether a mobile terminal device is in a WLAN or not are also known and are sometimes used as WLAN scanners or sniffers A mobile radio terminal is, in particular, a cell phone or a portable PC that realizes the above-mentioned functionalities.

The invention allows such mobile radio terminals to be connected in a cost-effective manner to cost-effective data transmission using VoIP and WLAN technologies. As soon as the cell phone subscriber is in a WLAN and has registered, calls are routed to the subscriber via the IP network and the WLAN, avoiding roaming costs.

In a preferred embodiment of the invention, in the event that it is ascertained that the mobile radio terminal is in a WLAN and after the mobile radio terminal has registered and authenticated in the WLAN, call forwarding is activated which is based on the mobile telephone number of the mobile terminal to these calls from the mobile network to the telecommunications device. For this purpose, a control signal for Activation of the call diversion sent out by the telecommunications device or the mobile radio terminal. The control signal for activating the call diversion is triggered, for example, by a certain key combination which the user of the mobile radio terminal enters into it, and is communicated to it via the mobile radio network. Furthermore, the control signal can also be generated automatically (for example by means of a software procedure) if the mobile radio terminal determines that it is in a WLAN. The control signal can be transmitted as part of an out-of-band or in-band signaling. This variant of the invention ensures that when the called mobile radio terminal enters a WLAN area, incoming calls are routed to the telecommunications device, which then sends the data associated with the call to the WLAN via IP packets.

Furthermore, it is preferably provided that the mobile radio terminal, when it is located in a WLAN, notifies the telecommunications device of a fixed or dynamically assigned IP address. On the basis of the call diversion set up, incoming data of a TC connection to the mobile radio terminal are then provided with the communicated IP address by the TC device and sent to the IP network. In particular, the data of the telecommunications connection under consideration, provided with the IP address, are packet-switched by the telecommunications device as VoIP data to the router of the WLAN and transmitted from there via the WLAN to the mobile radio terminal.

When the mobile terminal leaves the WLAN, the call diversion is deactivated, either automatically or via active user signaling.

The TC device is preferably a gateway which is connected on the one hand to a packet switching network, in particular the Internet, and on the other hand to a mobile radio network and / or a circuit-switched TK fixed network, in particular the PSTN (Public Switched Telephony Network) . In an alternative embodiment of the invention, the PBX is a PBX, the extensions of which are mobile radio terminals, according to claim 1, calls to an extension being routed by the PBX either via the mobile radio network or via the WLAN, depending on whether the extension is in the WLAN or not. With this variant, the data of the communication link under consideration are always sent to the PBX first, regardless of the network over which the data is forwarded.

In a preferred embodiment of this embodiment, the data of a call directed to an extension, in the event that the extension is not in a WLAN, is routed from the PBX to the extension via the mobile radio network, the extension Call number is assigned a number in the mobile network and the extension is called by the PABX under this mobile phone number. There is a transparent number assignment for the caller in the PBX.

Furthermore, it is preferably provided that in the event that the extension is in a WLAN, the extension communicates a fixed or dynamically assigned IP address to the PBX, and then incoming data of a PBX connection to the extension from the PBX be provided with the IP address of the extension. In particular, the data of the considered PBX connection provided with the IP address are packet-switched by the PBX as IP data packets to the router of the WLAN and from there via the WLAN to the mobile radio

Transfer terminal. The trigger for the alternative routing via the WLAN is the communication of the IP address of the extension to the PBX. The resulting alternative routing can also be seen as a kind of call forwarding. The mobile radio network is based, for example, on one of the standards GSM, UMTS or CDMA. For example, the WLAN is based on one of the standards WiFi, WiMAX or Bluetooth. However, any other mobile radio and WLAN technologies can also be used.

The telecommunication arrangement according to the invention has a mobile radio terminal and a telecommunications device. The mobile radio terminal comprises an access module to a mobile radio network, a WLAN access module to a WLAN, a Voice-over-IP (VoIP) functionality, and means for determining whether the mobile radio terminal is in a WLAN or not. The TC device is set up in such a way that it provides data of a TC connection to the mobile radio terminal with the IP address of the mobile radio terminal and sends it out to a packet switching network, in particular the Internet, provided the mobile radio terminal is in a WLΛN located. The data is then transmitted to the WLAN and mobile radio terminal using standard Internet routing.

Description of several preferred exemplary embodiments

The invention is explained in more detail below with reference to the figures using several exemplary embodiments. Show it:

FIG. 1 shows a first exemplary embodiment of a telecommunication arrangement which allows calls directed to a mobile radio terminal to be routed via a WLAN, with an illustration of a registration process and the implementation of a call diversion,

Figure 2 shows the telecommunications arrangement of Figure 1 with

Representation of the TC networks involved in a TC connection to the mobile radio terminal in the event that the cellular terminal is in a WLAN; FIG. 3 shows the telecommunications arrangement of FIG. 1, showing a deregistration and deactivation of call diversion in the event that the mobile radio terminal is no longer in a WLAtST;

FIG. 4 shows a second exemplary embodiment of a telecommunication arrangement which allows calls directed to a mobile radio terminal to be routed via a WLAN,

5 shows the telecommunication arrangement of FIG. 4, the mobile radio terminal being outside a WLAN, and FIG. 6 components of the mobile radio terminal of FIGS. 1 to 5 in one exemplary embodiment.

FIG. 1 shows a telecommunication arrangement with a TC terminal 1, a mobile radio terminal 2, a WLAN 3, an IP network 4 _r, a mobile radio network 6, a circuit-switched telephone network 7 and a gateway 5.

The TK terminal 1 can be any terminal, for example an analog telephone, an ISDN telephone, a cellular telephone, an IP telephone or a PC. The TC terminal 1 can be connected in any way to a telecommunications network, for example via a local exchange to the public telephone network PSTN 7 or to a mobile radio network 6, or via a DSL connection to the Internet.

The mobile radio terminal 2 is, for example, a mobile telephone or a portable PC. FIG. 6 shows an example and a schematic representation of the structure of the mobile radio terminal 2, insofar as it is of interest here. An access module 21 is connected to a central control unit CPU 24 with an associated memory 25 and an input / output unit 26 Mobile radio network 6 and a WLAN access module 22 connected to WLAN 3. A VoIP module 23 (which can be designed as software) is assigned to the WLAN access module 22, or the latter is integrated in the former. The VoIP module 23 packets and depacts data. Incoming IP data packets are depacketized and sent to the CPU 24 as digital data. Digital, non-packetized data arriving from the CPU 24 are packetized as IP packets and sent to the WLAN access module. Furthermore, a so-called sniffer 27 is connected to the CPU 24, which determines whether the mobile radio terminal 2 is in a WLAN. In this case, a corresponding control signal is output to the CPU 24, which then activates the WLAJSF access module 22 in such a way that it registers and authenticates in the existing WLAN. Such WLAN sniffers are well known to the person skilled in the art, so that their structure is not explained in detail.

The access module 21 to the mobile radio network is preferably a GSM module or a UMTS module, which is also referred to as a GSM engine or UMTS engine. A SIM card, not shown, is assigned to module 21. A SIM card is a plug-in card with an identifier that is used to assign a mobile radio device to a specific network operator, to assign a specific phone number and to be uniquely identifiable in all mobile radio networks.

The WLAN access module 22 permits data transmission from and to the mobile radio terminal 2 via the WLAN 3. The data are transmitted as IP packets via the WLAN. Such data transmission is also known as VoWLAN (Voice over WLAN).

As will be explained further, in one embodiment variant the mobile radio terminal 2 generates a control signal for activating call forwarding under certain conditions. The call diversion provides that 6 incoming incoming calls that are directed to the mobile radio terminal 2 are diverted to the gateway 5. The control signal for activating call forwarding is triggered, for example, by a certain key combination. A control logic for generating a control signal for a call diversion is preferably generated by the CPU 24 together with programs stored in the memory 25 and possibly input information from the input / output unit 26. The generated control signal is preferably transmitted to the mobile radio network S via the access module 21.

The WLAN 3 is a wireless local radio network that works according to any standard, such as WiFi (Wireless Fidelity), WiMAX (worldwide interoperability for microwave access) or bluetooth. The WLAN 3 has a WLAN hotspot 31, which is a technical device which provides the mobile radio terminal 2 and other terminals arranged in the WLAN with access to the Internet. The WLAN hotspot 31 comprises a WLAN router and an authentication unit which carries out and monitors the registration, user authorization and billing processes. The structure of a WLAN hotspot 31 is known to the person skilled in the art, so that it is not dealt with in more detail here. The IP network 4 is, in particular, the Internet. In principle, however, any packet-switched network can be provided. The WLAN hotspot 31 is connected to an Internet service provider ISP of the Internet 4 (not shown separately), this connection preferably being a broadband connection, for example via DSL technology.

The ISP then provides a connection to the Internet 4.

The mobile radio network 6 can be any mobile radio network, in particular based on the standards GSM, UMTS or CDMA.

The telephone network 7 is preferably the PSTN (public switched telephone network), the telephone calls and other services such as fax brokered. It generally stands for any line-switched telecommunications network in which dial-up connections are switched and switched through. The gateway 5 shown further in FIG. 1 provides a transition between the IP network 4 on the one hand and the telephone network 7 and / or the mobile radio network 6 on the other hand, which will be discussed in more detail below. The situation is considered that the mobile radio terminal 2 has registered and authenticated in the mobile radio 6 and is ready to receive data via the mobile radio network 6, for example data from a telephone call, an SMS, a video or an e-mail.

If the mobile radio terminal 2 now uses the module 27 to determine that it is in a WLAN 3, two processes are triggered. One process comprises the registration of the mobile radio terminal 2 with the gateway 5 (arrow A in FIG. 1). When the mobile radio terminal 2 registers with the gateway 5, it notifies the gateway 5 of its IP address. The registration of the mobile terminal 2 at the gateway 5 is preceded by the registration of the terminal 2 in the WLAN 3. This is done via the WLAN

Access module 22 and the WLAN hotspot 31, which, as mentioned, comprises a WLAN router and a module for authentication, authorization and billing of WLAN connections. The router of the WLAN hotspot 31 assigns a dynamic IP address to the mobile radio terminal 2 during the registration process. Alternatively, the mobile radio terminal has a fixed IP address, but this will usually not be the case. After registration of the mobile radio terminal 2 at the WLAN hotspot 31, the mobile radio terminal 2 has access to the Internet 4 and, via the Internet 4, access to the gateway 5. It is now possible to use the Internet (fixed or dynamically assigned by the WLAN hotspot 31) Communicate address to gateway 5. The other process implements a call diversion in the mobile radio network 6. The call diversion provides that calls arriving in the mobile radio network 6, which are directed to the mobile radio terminal 2 under its mobile radio number, are diverted to the gateway 5. The gateway 5 has its own fixed number.

The call diversion can be initiated either by the mobile radio terminal 2 (arrow B in FIG. 1) or alternatively by the gateway 5 (arrow C in FIG. 1). It can be done by in-band signaling (e.g. via DTMF), by "direct" out-band signaling or by "indirect" out-band signaling. A direct out-of-band signaling is, for example, a signaling triggered directly by a user, such as pressing a specific star-hash combination on the input keys of the mobile radio terminal 2. This data can be sent as an out-of-band signaling to the mobile radio network 6 as an out-of-band signaling be transmitted. An indirect outer band

Signaling includes, for example, a pre-configuration on a web interface of a screen or display of the mobile radio terminal 2 (for example a cell phone display or the screen of a laptop).

The call diversion can thus be triggered, for example, by the mobile radio terminal 2 by pressing a specific key combination or automatically in accordance with a pre-configuration. The pre-configuration provides that in the event that the presence in a WLAN area is detected, a signal for call forwarding is automatically generated.

The call diversion can also be carried out by the gateway 5. The gateway 5 carries out a call diversion, for example, when it is transmitted from the mobile radio terminal 2 via the latter

IP address is informed. In addition to the IP address, the The conventional telephone number of the mobile radio terminal 2 in the mobile radio network 6 is also communicated to the gateway 5, or this is already known to the gateway 5, so that the gateway 5 can make an assignment and can inform the mobile radio network 6 accordingly. The signaling between the gateway 5 and mobile radio network 6 can in turn take place as in-band or out-of-band signaling.

It is pointed out that in a corresponding manner, ie triggered by the mobile radio terminal 2 or by the gateway 5, the call diversion can also be deactivated. This will be explained further in FIG. 3.

FIG. 2 now shows the situation that a connection is made from the calling TC device 1 to the mobile radio device 2 in the event that the mobile radio terminal 2 is located in the WLAN 3. Since the call to the mobile radio terminal 2 takes place by typing in its mobile telephone number, the call is first routed to the mobile radio network 6. As already explained, the terminal 1 can be connected directly to the mobile radio network 6 or, alternatively, can be connected to the latter via further interposed networks such as the PSTN. Based on the call diversion set, the incoming call is forwarded to the gateway 5. In the exemplary embodiment shown, the call is diverted via the PSTN 7, ie the call is first forwarded to the PSTN 7 and in this to the gateway 5, which has a specific call number in the PSTN 7. Alternatively, it can also be provided that the call from the mobile radio network 6 is routed directly to the gateway 5 without the PSTN 7 being interposed. In the latter case, the gateway 5 would have a direct interface to the mobile radio network 6. It is also conceivable that the call is routed from the mobile radio network 6 to the gateway 5 not only via a network 7, but via a plurality of interconnected networks. It is pointed out that the term "call" in the sense of the present invention is used as a short name for the transmission of data in a TC connection between the TC terminal 1 and the mobile radio terminal 2. This data includes signaling data when establishing a connection When establishing the connection, this data includes useful data, for example voice data, video data or text data. No distinction is made between such signaling data for establishing a connection and useful data after establishing a connection. The routing described affects both the signaling data and the useful data.

In addition, it is noted that it is essential for the invention that the transmission of the user data takes place via the described routing. If an alternative signaling should take place with direct communication between the mobile radio network 6 and the mobile radio terminal 2 for establishing a connection, the method described would not be affected, provided the user data streams continue to experience the described routing.

The gateway 5 has learned the IP address of the mobile radio terminal 2 due to the described registration of the mobile radio terminal 2 with the gateway 5. Data is now converted in such a way that the received data are packed in IP packets and sent as VoIP packets to the Internet 4 to which the gateway 5 is connected or of which it is part. On the Internet 4, the IP packets with the address information of the mobile radio terminal 2 experience a normal routing. The packets are accordingly routed to the WLAN hotspot 31 and are transmitted from there to the mobile radio terminal 2 as IP packets using WLAN technology (for example WiFi, WiMAX or Bluetooth). There they are received by the WLAN access module 22. catch, depacketized and displayed or output as voice data, video data or text data in the mobile radio terminal.

Only the charges of the operator of the mobile radio network 6, pass-through fees of the operator of the network 7 and fees of the operator of the WLAN hotspot 31 are incurred during the transmission. Not against an operator incurred roaming charges of another mobile network, which would use the mobile terminal 2, if it does not catch area is his "own ^w mobile network in recom-.

FIG. 3 shows the situation in which the mobile radio terminal 2 has left the WLAN 3 again. According to arrow D, the mobile radio terminal logs off at gateway 5 again. This can be done directly, for example by sending an SMS from the mobile radio terminal 2 to the gateway 5. This can also be done indirectly, for example, by the gateway 5 and the mobile radio terminal 2 transmitting so-called life messages between them, which confirm the existence of a connection. If the mobile radio terminal 2 leaves the WLAN 3, the gateway 5 no longer receives life messages from the mobile radio terminal 2 and interprets this as a deregistration.

Furthermore, when the mobile radio terminal 2 leaves the WLAN 3 again, the call diversion is deactivated either by the mobile radio terminal 2 or by the gateway 5 according to the arrows E, F. A call to the mobile radio terminal 2 under its mobile radio number is now established again directly via the mobile radio network S or mobile radio networks cooperating with the mobile radio network 6 via roaming agreements. If the mobile radio terminal 2 is again in a WLAN 2, the method according to FIGS. 1 and 2 is carried out again.

The method of FIGS. 1 to 3 is further explained using the specific example. It is assumed that the mobile radio terminal in the cellular network 6 has the number 0172xxxxxx. It is also assumed that the gateway in the telephone network 7 has the number 030yyyyyy. A call sent by the telecommunications terminal 1 after 0172xxxxxx is forwarded to the number 030yyyyyy in the mobile radio network S and is routed via the PSDN network 7 for this purpose. The incoming call is assigned to the IP address of the mobile radio terminal 2 in the gateway 5. The data are then sent via IP telephony to the WLAN hotspot 31 and from there to the mobile radio terminal 2. The call number is assigned in a manner known per se, for example using the SIP protocol (Session Initiation Protocol). This allows end devices to log on to a central SIP server for a limited time in order to leave their own IP address there. This can then be requested from other SIP endpoints. The SIP protocol is known to the person skilled in the art, so that it will not be discussed further here. Alternatively, the H.323 protocol can also be used. The call is therefore directed to the address SIP-xxxxxx, which corresponds to the IP address of the mobile radio terminal 2.

If the mobile radio terminal 2 is removed from the WLAN, the call forwarding for 0172xxxxxx is removed and incoming calls are sent directly to this number via the mobile radio network 6 or via roaming agreements with the mobile radio network. Cellular terminal 2 passed.

FIGS. 4 and 5 show an alternative exemplary embodiment of the present invention. According to FIGS. 4 and 5, a telecommunications system 8 is provided, to which a large number of extensions 2 are connected. The extensions are each designed as mobile radio terminals in accordance with the configuration in FIG. 6. Only one of the several extensions or mobile radio terminals is shown in FIGS. 4 and 5.

The communication between the PBX 8 and the extensions normally takes place via a cellular network 6. There are In this respect, the PABX 8 is not a "classic" PABX to which terminals or extensions are connected by cable. The PABX 8 is rather a switching device to which several mobile radio terminals are connected a cellular network is connected.

If, according to FIG. 4, the mobile radio terminal 2 is in a WLAN 3, it communicates this to the PBX 8, as explained in relation to FIGS. 1 and 2. This then routes incoming connections via the IP network 4 and the WLAJST hotspot 31 to the mobile radio terminal 2. The mobile radio network 6 is not used, so that costs for its use are eliminated.

If, according to FIG. 5, the mobile radio terminal moves away from the WLAN 3 again, the mobile radio terminal 2 logs off from the telecommunications system 8 and incoming calls are now routed back to the mobile radio terminal 2 via the mobile radio 6.

This is explained further using an example. It is assumed that a call is sent from the telecommunications terminal 1 to the extension 123 of the telecommunications system. The extension has the number 030 4711-123. In the normal case, when the extension 123 is not in a WLAN 3, the call of the mobile radio network 6 is transmitted to the extension according to FIG. A certain mobile phone number 0172xxxxxx is assigned to extension 123. The address translation from extension 123 to mobile phone number 0172xxxxxx is carried out by PBX 8.

If, on the other hand, the mobile radio terminal 2 is located in a WLAN 3 according to FIG. 4, the call is routed to the WLAN hotspot 31 via Internet telephony and SIP protocol and to the mobile radio terminal 2 via the WLAN. The number 030 4711-123 of the extension is assigned the SIP number SIP: 123. The SIP phone number encodes the IP address the mobile radio terminal 2 has (due to a dynamic assignment or as a fixed address).

The embodiment of the invention does not relate to the exemplary embodiments described above. In particular, the mentioned mobile radio networks and technologies and the mentioned WLAN technologies are only to be understood as examples. Furthermore, the fulfillment is not limited to the transmission of voice data. It also affects the transmission of messages, text and video.

Claims

Claims

1. Method for routing data of a telecommunications

(TC) connection between a calling TC terminal (1) and a called cellular terminal (2), the cellular terminal (2) having

 an access module (21) to at least one mobile radio network (6),

 a WLAN access module (22) to a wireless LAN (WLAN) (3),

 a Voice-over-IP (VoIP) functionality (23), and means (27) for determining whether the mobile terminal

(2) is in a WLAN (3) or not, with the steps:

 - determining whether the mobile radio terminal (2) is in a WLAN (3),

 if the mobile radio terminal (2) is not in a WLAN (3), route the data of a TC connection to the mobile radio terminal (2) via at least one mobile radio network (6) to the mobile radio terminal (2), provided that the mobile terminal (2) in a WLAN

(3) located

 o Register in the WLAN (3) using the WLAN

Access module (22), and

 o Providing an alternative routing of the data of a telecommunications connection to the mobile radio terminal (2), o the alternative routing being a routing of the data as IP data from a telecommunications device (5, 8) to a router (31) of the WLAN (3) and from this via the WLAN (3) to the mobile radio terminal (2).

2. The method according to claim 1, characterized in that the alternative routing further comprises a call diversion, which is directed to this calls from the mobile radio network (6) to the telecommunications device (6) under the mobile radio number of the mobile radio terminal (2). 5) redirects.

3. The method according to claim 2, characterized in that a control signal for activating the call diversion is sent out by the TC device (5).

4. The method according to claim 2, characterized in that a control signal for activating the call diversion is sent out by the mobile radio terminal (2).

5. The method according to claim 4, characterized in that the control signal for activating the call diversion is triggered by a certain key combination which the user of the mobile radio terminal (2) enters into it.

6. The method according to claim 3 or 4, characterized in that the control signal is generated automatically when the mobile radio terminal (2) determines that it is in a WLAN (3), and then in the WLAN (3) has registered.

7. The method according to any one of the preceding claims, characterized in that the mobile radio terminal (2), if it is in a WLAN (3) and has registered, the telecommunications device (5) has a fixed or dynamically assigned IP address communicates.

8. The method according to claims 2 and 8, characterized in that the telecommunications device (5) provides data that it receives due to the call diversion set up with the communicated IP address and sends it out as IP data.

9. The method according to claim 8, characterized in that the data provided with the IP address of the telecommunications connection under consideration is packet-switched from the telecommunications device (5) as IP data to the router (31) of the WLAN (3) and from - sem be transmitted via the WLAN (3) to the mobile radio terminal (2).

10. The method according to any one of claims 2 to 9, characterized in that when leaving the mobile terminal

(2) of the WLAN (3) the call diversion that has taken place is deactivated.

11. The method according to any one of the preceding claims, characterized. characterized in that the telecommunications device (5) is a gateway which is connected on the one hand to a packet switching network (4) and on the other hand to a mobile radio network (6) and / or a circuit-switched telecommunications fixed network (7).

12. The method according to claim 1, characterized in that the telecommunications device (8) is a telecommunications system, the extensions (2) of which are mobile radio terminals according to claim 1, and calls directed to an extension (2) and associated Data from the PBX (8) via the cellular network (6) or in the alternative routing via the WLAN (3) are routed, depending on whether the extension (2) is in the WLAN (3) or not.

13. The method according to claim 12, characterized in that the data of a call directed to an extension (2) in the event that the extension (2) is not in a WLAN (3) from the PBX (8) via the cellular network (6) to the extension (2), the extension number being assigned a number in the cellular network and the extension (2) being called by the PABX (8) using this cellular number.

14. The method according to claim 12, characterized in that in the event that the extension (2) in the WLAN

(3), the extension (2) of the PBX (8) one communicates fixed or dynamically assigned IP address, and incoming data of a PBX connection to the extension (2) is provided by the PBX (8) with the IP address of the extension (2).

15. The method according to claim 14, characterized in that the data of the considered telecommunication connection provided with the IP address is packet-switched from the telecommunication system (8) as VoIP data to and from the router (31) of the WLAN (3) are transmitted to the mobile radio terminal (2) via the WLAN (3).

16. The method according to any one of the preceding claims, characterized in that the mobile radio network (6) is based on one of the standards GSM, UMTS or CDMA.

17. The method according to any one of the preceding claims, characterized in that the WLAN (3) is based on one of the standards WiFi, WiMAX or Bluetooth.

18. A telecommunications arrangement for performing the method according to claim 1, which comprises:

 • a mobile radio terminal (2) with

 o an access module (21) to at least one mobile radio network (6),

 o a WLAN access module (22) to a wireless LAN

(WLAN) (3),

 o Voice-over-IP (VoIP) functionality (23), and o means (27) for determining whether the mobile radio terminal (2) is in a WLAN (3) or not,

• A TC device (5, 8) which is set up in such a way that it provides data of a TC connection to the mobile radio terminal (2) with the IP address of the mobile radio terminal (2) and sends it out to a packet switching network , provided the mobile terminal is in a WLAN (3).

19. Telecommunication arrangement according to claim 18, characterized in that the telecommunication device (5) is a gateway and provides and transmits data received in the context of a call diversion of a considered telecommunication connection with a fixed or dynamically assigned IP address which the gateway ( 5) received by the mobile radio terminal (2).

20. Telecommunication arrangement according to claim 18, characterized in that the telecommunications device (5) is a telecommunications system, the extensions (2) of which are mobile radio terminals according to claim 18, wherein calls to an extension (2) are made by the telecommunications system System (8) either via a mobile radio network (6) or via the WLAU (3), depending on whether the extension (2) is in the WLAN (3) or not.