Title of Invention

A METHOD FOR CIRCUIT-SWITCHED AND PACKET-SWITCHED COMMUNICATIONS

Abstract A communication system comprising: a network having a first network access point and .a second network access point and being capable of carrying data between the first network access point and the second access point by means of for example a packet-switched bearer and a circuit-switched hearer; and a first terminal capable of connection to the first network access point and a second terminal capable of connection to the second network access point, each terminal being capable of simultaneously supporting a packet-switched connection and a circuit-switched connectioh with the other terminal via the network as a single logical communication arrangement.
Full Text

CIRCjUIT-SWITCHED AND PACKET-SWITCHED COMMUNICATIONS
This iinventiorf, relates to establishing connections in a communication system such as a rpobiie telephony system.
Figure 1 is a simplified diagram of one form of communications system. The structure of figure 1 is based on the architecture of the third generation (3G) UMTS mobile communication system. The system of figure 3 includes two user equipment devices or terminals (UE) 1, 2 which are capable of communicating by means of a network 3. Each of the terminals communicates with the network by radio, and gains access to the network 3 via a radio access network (RAN) 4, 5. The network 3 provides for two forms of communication between the terminals. Circuit-switched connections, for example for voice communication, pass between the radio access networks 4, 5 via mobile switching centres (MSC) 6, 7. Packet-switched connections, for example for data connections, pass between the radio access networks via serving GPR^^ support node (SGSN) 8, 9 and gateway GPRS support node (GGSN) 10,1ll
Conventionally, when a connection is to be set up. between two terminals the terminals decide on the basis of the nature of the proposed connection - for example the required data rate and the amount of delay that can be tolerated - whether to set up a packet switched connection or a circuit-switched connection. Some applications can be satisfied by either type of connection. For example, in many situations voice traffic can be carried satisfactorily over a circuit switched connection or a packet switched connection (for example by means of the SIP or H.323 protocol). Especially with packet switched connections data of more than one form can be carried over the link, so that (for example) voice and video data could be carried simultaneously. This pbvides a convenient way to implement enhanced services such as click-to-talk whitebjoarding,and chatting.

HoweVer, packet-switched voice is relatively new. In most existing networks voice traffic is carried almost exclusively over circuit switched links because in those networks packet switched links cannot be guaranteed to provide a sufficient quality of service; for example due to the possibility of there being delay that is excessive for voice i traffic. It can be expected that in the future networks will be able to carry packet-switched traffic at a level of service that allows enhanced services of the types listed above to be supported reliably over packet-switched links. However, in the meantime, as demand for such enhanced services grows, there is a need to
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bridge the gap before packet switched networks of higher capability are generally available, and allow such enhanced sen/ices to be provided over more conventional netwol'ks. j
Furthermore, even when networks of higher capability are available it can be anticipated that in many cases circuit-switched and packet-switched channels will be
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available. The inventors of the present invention have noticed that in order to balance the utilisation of bandwidth over both parts of the network it would be useful to have additional flexibility in the allocation of connections to the available forms of
channel.
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According to one aspect of the present invention there is provided a communication system comprising: a network having a first network access point and a second network access point and being capable of carrying data between the first network access point and the second access point by means of a first bearer and a second bearer; and a first terminal capable of connection to the first network access point and a second ;"terminal capable of connection to the second network access point,
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each terminal being capable of simultaneously supporting a connection of a first type and a connection of a second type with the other terminal via the network as a single logical communication arrangement.
According to a second aspect of the invention there is provided a method for communicating between a first terminal and a second terminal by means of a communication system comprising a network having a first network access point and

a second network access point and being capable of carrying data between the first network access point and the second access point by means of a packet-switched bearer and a circuit-switched bearer; the method comprising: the first terminal connecting to the first network access point; the second terminal connecting to the second network access point; and each of the terminals simultaneously supporting a packet-switched connection and a circuit-switched connection with the other terminal via th 3 network as a single logical communication arrangement.
Preferably the first bearer is a packet-switched bearer and the type of the first connection is packet-switched. Preferably the second bearer is a circuit-switched
bearer and the type of second connection is circuit-switched.
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Preferably the terminals are arranged to perform an operation to establish the simultaneous packet-switched and circuit-switched connections by the steps of: establishing the circuit-switched connection; and each terminal transmitting its packet-switching address to the other terminal by means of the circuit-switched connection. Then preferably the terminals are arranged to establish the packet-switched connection by means of the packet-switching addresses transmitted over the circuit-switbhed connection.
Alternatively, the terminals may be arranged to perform an operation to establish the simultaneous packet-switched and circuit-switched connections by the steps of: establishing the circuit-switched connection; and each terminal communicating with a proxy server of the network to obtain from the proxy server the packet-switching address of the other terminal. Then each terminal may be arranged to provide the respective proxy server with a network address of the other terminal and the proxy server'is arranged to be responsive to that address to provide the packet-switching address of that other terminal. The network address may be an E.164 number. Suitably the terminals are arranged to establish the packet-switched connection by means! of the packet-switching addresses obtained by means of the proxy. The proxy may be a SIP proxy.

The dacket-switching addresses are suitably internet protocol addresses.
The [backet-sWitched addresses may be transmitted to the terminals by means of user-io-user signalling (UUS). The packet-switched addresses may be transmitted to the terminals by means of the session description protocol (SDP). Messages sent using UUS may conveniently be coded using the SDP protocol.
The terminals may be arranged to perform an operation to establish the simultaneous packet-switched and circuit-switched connections by the steps of: establishing the packet-switched connection; and each terminal transmitting its circuit-switching addrejss to the other terminal by means of the packet-switched connection. Then the terminals may be arranged to establish the circuit-switched connection by means of the cirfcuit-switching addresses transmitted over the circuit-switched connection.
The c rcuit-switching addresses are preferably mobile subscriber integrated services digital network identities (MSISDNs), i.e. E.164 numbers.
Suitably the dircuit-switching addresses are transmitted by means of the session initiation protocol (SIP).
The network is preferably a mobile communication network. The terminals are preferably mobile terminals. The terminals are preferably capable of communicating over the radio interface with the network. The network and/or the terminals may be operable according to the GSM, GPRS or UMTS systems or a derivative thereof. The network may comprise one ore more core networks.
The piesent invention will now be described by way of example with reference to the accompanying drawings, in which:
figure 1 is a schematic diagram of a communication network;
figure 2 shows a simplified functional architecture of a user equipment terminfil;

* figure 3 shows message flow during the setup of a whiteboard communication
session;
• figure 4 shows message flow during the continuation of a communication
session;
■ figure 5 shows another simplified functional architecture of a user equipment terminal;
figure 6 shows message flow during the continuation of a packet switched comniunication session by a circuit switched connection;
The present nvention will be described by way of example with reference to the architi3Cture ofi a 3G network. However, it will be understood that it can be applied to any oiher suitable form of network.
Numerous enhanced services that users of communication services are beginning to demand make use of both highly delay-critical data, such as voice information, and associated less delay-critical data. Examples of such less delay-critical data include images to support click-to-talk services, drawings that are to be shared in whiteboard services, and supporting data on participants' actions for supporting chat services. In each of these cases, voice data should be carried as normal with minimal delay, but the supporting data can tolerate more delay. As will be described below, these services can be conveniently supported by means of simultaneous circuit-switched and packet-switched links between common end-points or terminals. Such an arrangement can be implemented in a network of the schematic form shown in figure 1, but with the terminals / user equipment and the network-side components having the arc^hitecture and capabilities described below.
Figure 2 shows the functional architecture of a terminal suitable for acting as UE 1, 2 ^ in the,architecture of figure 1, and providing for simultaneous circuit-switched and packet-switched links between common end-points. The upper level 20 of the architecture is the user interface, which handles the interaction between lower-level components and the user. Below the user interface 20 is an application 21 running on the terminal. In this example the application is one that can support enhanced or

"rich call" services. Below the application are the layers that format outgoing data or process incoming data according to packet-switched or circuit-switched requi-ementsl In this example, the packet-switched (PS) layers comprise an upper interr et protojcol (IP) layer 22 and a gateway general packet radio service (G-GPRS) layer 23. The circuit switched (CS) processing is handled by a CS protocols layer 24. The ^S- anc'. OS-specific layers are effectively in parallel. Below the PS and CS layers is the radio interface to the 3G wide-band CDMA (W-CDMA).
In providing a rich call sen/ice the rich-call application (RCA) 21 is capable of communicating with both the PS-specific functionality 22, 23 and the CS-specific functionality 24. The RCA coordinates usage of CS and PS connections and provides a coherent user experience through the user interface when the service is in use.
When one terminal of the type illustrated in figure 2 is to communicate with another such terminal by means of a rich call service, the users of each terminal activate applications 21 on their respective terminals to support the service. The applications negotiate with each other over the network 3 to determine how the service is to be provided. One possible arrangement is for the terminals to agree that more delay-criticel data, such as voice data, will be sent over a circuit-switched connection between the terminals and that less delay-critical data, such as associated visual or descriptive data, will be sent over a packet-switched connection between the same terminals. Once the terminals have established that they both support such an
arrangement and have agreed to proceed, the terminals establish simultaneous
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circuit-switched and packet-switched connections over the network, and then proceed with communication to provide the service.
One preferred means by which the PS connection may be provided is the internet protocol (IP). In this case, the terminals should know each others' IP addresses and the port numtpers that are to be used in order to set up the combined CS and PS
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connejction. This information could be communicated between the terminals using

user-to-user signalling (UUS), for example. One specific approach is to use the session description protocol (SDP) with is defined in RFC-2327.
The information on terminals' IP addresses etc. could be sent during the call setup process or later during the call, for example if the users decide during a conventional call to activate an enhanced sen/ice. In normal circumstances the former approach would be preferred.
An example of the operation of the setup procedure will be described with reference to figure 3. The example of figure 3 shows the setting up of a whiteboard session between users termed Ann (A) and Bob (B). Figure 3 shows A's terminal 30 and B's termiral 31. Each terminal includes a rich call application 32, 33; an IP stack 34, 35 for handing PS communications; and a CS protocol processing arrangement 36, 37 for handling CS communications. The terminals are connected for CS comrr unicatioi via a mobile switching centre 38 of the network. For simplicity the PS units of the network are not shown.
In this example it is assumed that both terminals initially have active PDF contexts with a'ssigned IP addresses. Otherwise, this could be arranged before further setup proceeds.
In the' process illustrated in figure 3, Ann's terminal displays an icon on which Ann
clicks :(at 40) to initiate a call. The RCA 32 interprets the request and determines that
I it would be preferred to satisfy the request for a call by means of a CS connection.
Accordingly, the terminal 30 and the terminal 31 communicate in the normal way as
showr in steps 41 to 50 to establish a CS call between the terminals and to open a
path for speech using a CS bearer channel.
The tejrminals Isuitably exchange SDP information with each other via UUS during call setup.

Then Bob decides to open a whiteboard session (at 51). The RCA 33 determines that parallel CS and PS connections should preferably be used to satisfy the requirement for voice and whiteboard data. Accordingly, the application 33 signals
the IP stack 35 to initiate the whiteboard session (at 52). With knowledge of the IP
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address of terminal 30 the terminal 31 signals terminal 30 to invite it to initiate a whiteboard session over a parallel PS link (at 53). The IP stack 34 signals the RCA 32 that a whiteboard session is requested (at 54). Ann indicates via the user interface of tsrminal 30 that she accepts the whiteboard session (at 55). RCA 32 signals to IP stack that the request is accepted (at 56) and IP stack 34 returns a 200 OK nessage! (at 57) to IP stack 35, which indicates (at 58) to the RCA that the whiteboard session is established. The whiteboard session may then continue using
a packet-switched bearer channel, as indicated at 59.
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As illustrated in figure 4, the session may continue by Ann requesting to book a meeting with Bob. To do so, meeting information is exchanged as illustrated generally at 60 using a further PS exchange. This exchange does not result in an ongoing communication session / channel of the form illustrated at 59.
When the call is to be ended Ann signals the RCA 32 that the call is to be ended (at
61). The RCA signals the IP stack 34 that the ongoing whiteboard session is to be
endec (at 62) and signals the CS protocols 36 that the CS call is to be ended (at 62.
63). Disconnect messages 64, 65 are sent in the normal way. The CS protocols 37
infornr the RC'A 35 of the party that did not initiate the termination that the call is to be
disconnected (at 66), that RCA 35 informs the IP stack 36 that the whiteboard
session is to be ended and acknowledges to the CS protocols the disconnection of
the call (at 67 and 68). Acknowledgements 69, 70 71 are then sent in the normal
way. The CS and PS connections are handled as a single logical communication
I arrangement. This linkage of the connections means that it is straightfon^/ard for the
terminal to terminate one of the connections if the other is terminated.

The jend-user application manages the number and nature of the connections transparently from the user's point of view, so that for the user the connections can be made andlterminated straightfonA/ardly even though they are of different types.
Figures 5 and 6 illustrate another arrangement. In the embodiment of figures 5 and 6 the terminals of A and B include an adaptation layer 80 (see figure 5). The adaptation layer allows the establishment of CS or PS calls to be transparent to the application 81 that is running on the terminal. The adaptation layer can be provided in the terminals independently of any application that is to run on them. The adaptation layer sits between the application and the CS and PS communication , layers. When the application issues a request for a connection the adaptation layer interprets that request and passes it to the CS or PS layers as appropriate.
Figure 6 shows an example of an operation that is supported by terminals having the architecture shown in figure 5. In the example of figure 6 it is supposed that two terminals 90, 91 are already communicating by means of a packet switched
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conneiction (see 92). The terminals have application layers 93, 94; adaptation layers 95, 96; IP stacks 97, 98 and circuit switched protocol stacks 99, 100. The terminals can communicate for CS calls via MSC 101.
User A decides to initiate a voice call with user B. User A signals the application layer 93 of her terminal to indicate that the voice call should be initiated (at 102). Since the terminals are already engaged in a PS call, in this example it is supposed that the application layer initiates the voice call by means of a request (fomnatted for example as indicated in figure 6) based on the address of the counterparty terminal as appropriate for a PS connection, e.g. in SIP (session initiation protocol) format. The adaptation layer could attempt to initiate the voice call over a PS link. However, in thiSj example it is assumed that the adaptation layer decides that a CS bearer should be used. This decision could be made based on the adaptation unit's knowledge of :he network's capabilities. As shown in figure 6, the adaptation layer sends an SIP INVITE message via the IP stack 97 to B's terminal. The INVITE messalge contains SIP parameters indicating that a CS bearer should be used and

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indicates the MSISDN of A's terminal (see 103). Knowledge of this MSISDN will enable B*s terminal to identify the call when the setup request for the call arrives at B's terminal.
The adaptation layer in B's terminal detects the incoming INVITE message. Since the form of the INVITE message indicates a request for an incoming CS call it responds with a 200 OK message including the MSISDN of terminal 8 (see 104). Know edge of the MSISDN of terminal B will enable terminal A to call that MSISDN to set up the impending CS call.
When! the UK message with the MSISDN of terminal B arrives at terminal A the adaptation layer 95 of terminal A begins to establish a call to that MSISDN (see 105). The adaptation layer 98 of the receiving terminal compares the MSISDN of the incoming call to the one received in step 103. Since they match, it informs the application layer 100 of terminal B of the incoming call (at 106). The application layer 100 which responds with an acceptance message 107 and in response the adaptation layer 98 accepts the CS call (at 108). The CS call is then established (at 109) at the same time, and between the same end-points as the original IP connection 92,
The same procedure can be used if SIP proxies (or CSCFs) are involved.
Other fneans may oe used to establish the PS connection.
If two convent onal GPRS (general packet radio service) terminals are engaged in a circuit-switcheij call, each knows the other's E.I64 number, but neither necessarily knows the other*s IP address as assigned by the GGSN. In this case, if a PS connection is then to be established in parallel with the existing CS connection there is a need for a means for the terminals to access each other's IP address and any necessary firewall and/or proxy traversal information.

In this situation the SIP protocol (RFC-2543), which was originally designed for voice-over-IP calls, can be used whilst the CS call is in progress. In order to determine the SIP URL of a CS user, there is preferably a predefined mapping from E.164 identities • to SIP URLs.j This mapping may make use of a predefined logic, or may tie stored as a Ipok-up table. Such addrpss mapping can be performed by the SIP proxy in the network (120 in figure 1). It may implement a simple mapping table, or may use a more complex database which has to be searched to determine a mapping. In the former solution, the look-up table could list the SIP proxy corresponding to each E.164 number, for example:
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E.164 Number SIP Proxy Operator
+358 40 sip.soneragprs.fi SONERA
+358 41 sipgw.teliagprs.com TELIA
+ 1 30 mcigprs.com MCI
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In the latter solution, the SIP proxy may provide in essence a DNS (domain name service) query service using DNS SRV records.
Durinij a CS ciall, users know the E.164 address of the remote party. The application at an initiating terminal that is to initiate the PS bearer connection to another terminal uses 1he E.164 address to create a SIP INVITE (or SIP INFO) message and sends it to the local SIP proxy. The destination is the E.164 number of the other party (sent with a tag to indicate that the address is a phone number instead of a user name) and that local proxy uses its mapping table (or a more complex scheme) to determine the corresponding destination SIP proxy. The identity of the destination SIP proxy is returned to the initiating terminal. The initiating terminal sends an INVITE (or INFO) message to that destination proxy indicating the E.164 identity of the other terminal. The destination proxy determines the SIP URL address that has been allocated to the terminal using that E.164 identity. The destination proxy can then forward that request to the said other temiinal by means of its IP address, and the setup of the PS conneption can continue generally as normal. Note that the destination proxy can

determine frolrn the fact that there is no session information in the payload of the
INVIT E (or INFO) message that the message does not indicate a call setup.
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Appropriate billing procedures can be applied, for example based on the parsed payload type or the size of the data to be transported. For example large uncorhpressed image files can be made more costly to transfer than smaller compressed image files. The SIP proxies can also maintain a register sen/ice which can apply different functions depending on the time of day, payload type etc. For instance, a user may define that if he receives a GIF image and the time is after 16:001 then the image is forwarded to an assigned e-mail address.
Alternatively, ,the SIP INVITE or INFO messages themselves could be used for transfsrring user data.
The present iivention has been described with specific reference to the UMTS and GPRS systenns. However, it is not limited to these systems.
The applicant draws attention to the fact that the present invention may include any feature or combination of features disclosed herein either implicitly or explicitly or any generalisation thereof, without limitation to the scope of any of the present claims. In view of the foregoing description it will be evident to a person skilled in the art that various modifications may be made within the scope of the invention.



CLAIMS
1. A communication system comprising:
a network having a first network access point and a second network access point and being capable of carrying data between the first network access point and the second access point by means of a first bearer and a second bearer; and
a first terminal capable of connection to the first network access point and a secorjd terminal capable of connection to the second network access point, each terminal being capable of simultaneously supporting a connection of a first type and a conncfction of .a second type with the other terminal via the network as a single logical communication arrangement.
2. A communication system as claimed in claim 1, wherein:
the first bearer is a packet-switched bearer and the type of the first connection is packet-switched; and
the second bearer is a circuit-switched bearer and the type of second connection is circuit-switched.
3. A communication system as claimed in claim 2, wherein the terminals are
arranged to perform an operation to establish the simultaneous packet-switched and
circuit-switched connections by the steps of:
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establishing the circuit-switched connection; and
each terminal transmitting its packet-switching address to the other terminal by
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meani) of the circuit-switched connection.
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4. A! communication system as claimed in claim 3, wherein the terminals are
arranged to establish the packet-switched connection by means of the packet-
switching addresses transmitted over the circuit-switched connection.
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5. A communication system as claimed in claim 2, wherein the terminals are
arranged to perform an operation to establish the simultaneous packet-switched and
circuit-switched connections by the steps of:

I
I establishing the circuit-switched connection; and each terminal communicating with a proxy server of the network to obtain from the prpxy server the packet-switching address of the other terminal.
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6. A :ommuriication system as claimed in claim 5, wherein each terminal is arranged
to provide the respective proxy server with a network address of the other terminal and the proxy server is arranged to be responsive to that address to provide the packet-switching address of that other terminal.
7. A.communication system as claimed in claim 5 or 6, wherein the terminals are arranged to establish the packet-switched connection by means of the packet-switching addresses obtained by means of the proxy.
8. A bommunication system as claimed in any of claims 3 to 7, wherein the packet-switching addresses are internet protocol addresses.
9. A communicaiion system as claimed in any of claims 3 to 8, wherein the packet-switched addresses are transmitted to the terminals by means of user-to-user signal ing.
10. A communication system as claimed in any of claims 3 to 9, wherein the packet-
switched addresses are transmitted to the terminals by means of the session
description protocol.
11. A communication system as claimed in claim 2, wherein the terminals are
arranged to perform an operation to establish the simultaneous packet-switched and
circuitjswltched connections by the steps of:
establishing the packet-switched connection; and
each terminal transmitting its circuit-switching address to the other terminal by means; of the packet-switched connection.

12. !A communication system as claimed in claim 11, wherein the terminals are arranged to establish the circuit-switched connection by means of the circuit-switching addresses transmitted over the packet-switched connection.
13. A communication system as claimed in claim 11 or 12, wherein the circuit-switching addresses are mobile subscriber integrated services digital network identities.
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14. A communication system as claimed in any of claims 11 to 13, wherein the
circuit-switching addresses are transmitted by means of the session initiation
protocol. I
15. A method for communicating between a first terminal and a second terminal by
means of a communication system comprising a network having a first network
accesis point and a second network access point and being capable of carrying data
between the first network access point and the second access point by means of a
packet-switched bearer and a circuit-switched bearer; the method comprising:
i the first terminal connecting to the first network access point; the second terminal connecting to the second network access point; and each of the terminals simultaneously supporting a packet-switched connection
and a circuit-switched connection with the other terminal via the network as a single
logical communication arrangement.
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16. A method as claimed in claim 15, wherein the terminals are arranged to perform
an operation to establish the simultaneous packet-switched and circuit-switched
connections by the steps of:
establishing the circuit-switched connection; and
each terminal transmitting its packet-switching address to the other terminal by means of the circuit-switched connection.

17. A method as claimed in claim 16, wherein the terminals are arranged to establish
the packet-switched connection by means of the packet-switching addresses
transmitted over the circuit-switched connection.
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18. A method as claimed in claim 16, wherein the terminals are arranged to perform
an o Deration to establish the simultaneous packet-switched and circuit-switched connections by the steps of:
establishing the circuit-switched connection; and
each terminal communicating with a proxy server of the network to obtain from the proxy server the packet-switching address of the other terminal.
19. A method as claimed in claim 18, wherein each terminal is arranged to provide the respective proxy server with a network address of the other terminal and the proxy server is arranged to be responsive to that address to provide the packet-switching address of that other terminal.
20. f method as claimed in claim 18 or 19, wherein the terminals are arranged to establish the packet-switched connection by means of the packet-switching addresses obtained by means of the proxy,
21. A method as claimed in any of claims 15 to 20, wherein the packet-switching addresses are internet protocol addresses.
22. A method as claimed in any of claims 15 to 21, wherein the packet-switched addresses are transmitted to the terminals by means of user-to-user signalling.
23- A method as claimed in any of claims 15 to 22, wherein the packet-switched addresses are transmitted to the terminals by means of the session description protocol.

24. ^ method as claimed in any of claims 15 to 23, wherein the terminals are
arranged to perform an operation to establish the simultaneous packet-switched and
circuit-switched connections by the steps of:
.' establishing the packet-switched connection; and each terminal transmitting its circuit-switching address to the other terminal by means of the packet-switched connection.
25. A method as claimed in claim 24, wherein the terminals are arranged to establish the circuit-switched connection by means of the circuit-switching addresses transmitted over the packet-switched connection.
26. A method as claimed in claim 23 or 24, wherein the circuit-switching addresses are mobile subscriber integrated sen/ices digital network identities.
27. A method as claimed in any of claims 23 to 25, wherein the circuit-switching
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addre sses are transmitted by means of the session initiation protocol.
28. A communication system substantially as herein described with reference to the accompanying drawings.
29. A method for communicating between a first terminal and a second terminal substantially as herein described with reference to the accompanying drawings.

A communication system substantially as herein above described with reference to the accompanying drawings. A method for communicating between a first terminal and a second terminal substantially as herein above described with reference to the accompanying drawings.


Documents:

2071-chenp-2003 abstract duplicate.pdf

2071-chenp-2003 claims duplicate.pdf

2071-chenp-2003 descripition completed duplicate.pdf

2071-chenp-2003 drawings duplicate.pdf

2071-chenp-2003 form 1.pdf

2071-chenp-2003 form 18.pdf

2071-chenp-2003 form 3.pdf

2071-chenp-2003 petition.pdf

2071-chenp-2003 power of attorney.pdf

2071-chenp-2003-claims.pdf

2071-chenp-2003-correspondnece-others.pdf

2071-chenp-2003-correspondnece-po.pdf

2071-chenp-2003-description(complete).pdf

2071-chenp-2003-drawings.pdf

2071-chenp-2003-form 1.pdf

2071-chenp-2003-form 3.pdf

2071-chenp-2003-form 5.pdf

2071-chenp-2003-pct.pdf


Patent Number 229209
Indian Patent Application Number 2071/CHENP/2003
PG Journal Number 12/2009
Publication Date 20-Mar-2009
Grant Date 13-Feb-2009
Date of Filing 29-Dec-2003
Name of Patentee NOKIA CORPORATION
Applicant Address Keilalahdentie 4, FI-02150 Espoo,
Inventors:
# Inventor's Name Inventor's Address
1 SOININEN, Jonne Urheilukatu 32 A 11, Fin-00250 Helsinki,
2 USKELA, Sami Siltasaarenkatu 26 A 1, FIN-00530, Helsinki,
3 HONKO, Harri Tuomiokirkonkatu 38, C 17, FIN-33100 Tampere,
4 KOSKELAINEN Petri Nokia Corporation, Keilalahdentie 4, Fin 02150, Espoo,
PCT International Classification Number H04L 12/56
PCT International Application Number PCT/IB2002/003164
PCT International Filing date 2002-06-28
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 0115996.1 2001-06-29 U.K.