JP2008252313A - Radio communication terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio communication terminal which can changeover radio communication networks in a condition that it uses existing terminal or network, and correspond to a plurality of radio communication networks by low cost. <P>SOLUTION: The terminal is provided with: a first radio communication means (an EV-DO reception unit 23a, an EV-DO transmission unit 23b); a second radio communication means (a radio LAN reception unit 24a, a radio LAN transmission unit 24b); and a handing off control unit 17 and a SIP (Session Initiation Protocol) control unit 19 which notice to a partner terminal of the communication that the communication is changed to an IP address acquired from the second communication system using a SIP message if it is discriminated to perform the communication changing over from the first communication means to the second communication means when the terminal performs the communication through the first communication means with the partner terminal whose call connection is established using the SIP. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless communication terminal using SIP (Session Initiation Protocol) as a communication control protocol.

Conventionally, in an IP (Internet Protocol) telephone communication system on the Internet, SIP has been used as a communication control protocol for managing call connection.
FIG. 18 is an explanatory diagram conceptually showing a conventional IP telephone communication system, and FIG. 19 is a sequence diagram for explaining a call by the IP telephone communication system of FIG. As shown in FIG. 18, the IP telephone communication system 1 includes an SIP server 2, IP telephones (terminal devices) 3 of a plurality of users (here, two users A and B are illustrated), and It has a plurality of routers 4 (here, four cases are illustrated) that relay between networks. Each IP telephone 3 is connected to a router 4 and connected to the SIP server 2 via a route selected by each router.

As shown in FIG. 19, when performing IP telephone communication, the user first sends his / her REGISTER authentication data, IP address (2.0.0.2), etc. from the IP telephone 3 to the SIP server 2. To be notified. Thereby, the SIP server 2 confirms the authentication data, and if OK, transmits an incoming notification (200 OK) to the corresponding user, and registers the IP address notified by the user in the information of the corresponding user.
When a call origination instruction is received from another user, if the destination user has already been registered, an incoming call notification is transmitted to the user. When receiving the incoming call notification, the user who has received the incoming call returns a reception ready notification to the SIP server 2, and then the SIP server 2 transmits an incoming call response to the calling user. Thereafter, the IP packet is directly exchanged between the source user and the destination user.

In this way, the user can perform IP telephone communication via the SIP server 2 without knowing the IP address of the other party.
Here, when the user (user B) moves and the IP address of the IP telephone 3 is changed (2.0.0.2 → 3.0.0.3) (see FIG. 18), Then, re-registration from the IP telephone 3 to the SIP server 2 (see FIG. 19) notifies that the IP address has been changed.
A system called MIP (Mobile IP) is also used under the idea that the IP address itself is not changed.

20 is an explanatory diagram conceptually showing another conventional IP telephone communication system, and FIG. 21 is an explanatory diagram conceptually showing a case where mobile communication is used in the IP telephone communication system of FIG. .
As shown in FIG. 20, in the IP telephone communication system 5 based on MIP, an HA (Home Agent) 6 serving as a relay server is installed between the SIP server 2 and each IP telephone (terminal device) 3. And a FA (Foreign Agent) 7 connected to each router 4. Other configurations are the same as those of the IP telephone communication system 1 (see FIG. 18).

When performing IP telephone communication by MIP, a user performs MIP registration for notifying authentication data and the like from the IP telephone 3 to the HA 6, authenticates with the HA 6, and is called HoA (Home Address) in the IP telephone 3. Have an IP address assigned. All the packets transmitted to the HoA are transmitted to the HA 6, and the HA 6 transfers it to the corresponding user. When authenticating with the HA 6, an IP address of the FA 7 called CoA (Care of Address) is also added to notify that the user is currently affiliated with the FA 7 network.
Here, when the user (user B) moves and the network to which the IP telephone 3 belongs changes accordingly (see FIG. 20), the user performs MIP registration with the HA 6 again, and the FA 7 (= CoA) is changed. Notify that something has changed.

  By the way, in the conventional SIP, it is created in consideration so that the user can specify wherever it is accessed (that is, the IP address is not fixed for each user). (See FIG. 18). For this reason, access is limited to standby, and there are a plurality of communication devices (mobile terminals, etc.) 8 whose IP addresses are changed during a call, and these are connected to EV-DO base station 9a and WLAN access point 9b. The case of the mobile communication connected to the network via the network (see FIG. 21) is not considered.

Therefore, when the conventional IP telephone communication method is applied to mobile communication having a plurality of communication devices, communication is disconnected if the IP address changes during communication. If MIP is used, the user's IP address will not be changed, but the entire network system needs to be recreated, so an increase in cost is inevitable.
Therefore, “user terminal switching method and user authentication method” (see Patent Document 1) has been proposed as a transfer destination designation method when a communication session is continued using a plurality of user terminals. In the “user terminal switching method and user authentication method”, communication is maintained with respect to a change in IP address during communication by a SIP server alone without using MIP.
JP 2005-64686 A

However, in the conventional “user terminal switching method and user authentication method”, it is necessary to always perform communication itself via the SIP server (service switching server), so the SIP server is used only at the start / disconnection of communication. During communication, it cannot be used in a normal IP telephone system that performs direct communication between users without going through the SIP server.
That is, in a mobile terminal that can use a plurality of wireless communication networks, communication is continued by switching the wireless communication network according to the wireless state or the communication state during communication. Therefore, the switching timing and the switching procedure with the communication partner become problems. In general, there is a method of using MIP to switch between a plurality of wireless communication networks, but as described above, enormous costs are required.

  An object of the present invention is to provide a wireless communication terminal capable of switching between wireless communication networks while using existing terminals and networks, and capable of supporting a plurality of wireless communication networks at low cost.

  In order to achieve the above object, a wireless communication terminal according to the present invention acquires an IP address from a first wireless communication system and performs communication using the first wireless communication system using the acquired IP address. A first wireless communication means, a second wireless communication means for acquiring an IP address from the second wireless communication system and performing communication using the second wireless communication system using the acquired IP address; When the communication with the counterpart terminal that has made a call connection using the Session Initiation Protocol) is performed via the first wireless communication unit using the IP address acquired from the first wireless communication system, When it is determined to switch from one wireless communication means to the second wireless communication means and perform the communication, the second terminal And a control means for controlling so as to notify the change to the IP address acquired from the second wireless communication system by the line communication means using a SIP message.

In this invention, the control means notifies the change to the IP address acquired from the second wireless communication system to the SIP server that performs call control using the SIP message, and from the SIP server in response to the notification. Based on the acquired IP address change time, the IP address acquired from the first wireless communication system is changed to the IP address acquired from the second wireless communication system, and the second IP address is used by using the changed IP address. It is preferable to control to perform the communication via a wireless communication unit.
In the present invention, when the control means detects that the received electric field strength of the second wireless communication system has exceeded a predetermined value, the control means switches from the first wireless communication means to the second wireless communication means. It is preferable to determine to perform communication.

Further, in the present invention, the control means uses the IP address acquired from the first radio communication system to communicate with the counterpart terminal that has performed call control using the SIP, via the first radio communication means. When the second wireless communication system is not detected, it is preferable that the second wireless communication means perform control so as to search for the second wireless communication system.
In the present invention, it is preferable that the second wireless communication system has a higher maximum system throughput than the first wireless communication system.
Also, in the present invention, it is preferable that the IP address acquired from the second wireless communication system is described and notified in a message (UPDATE) for notifying update of media negotiation by SDP (Session Description Protocol).

  According to the present invention, it is possible to switch between wireless communication networks while using existing terminals and networks, and it is possible to cope with a plurality of wireless communication networks at low cost.

The best mode for carrying out the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 is an explanatory diagram conceptually showing the IP telephone communication system according to the first embodiment of the present invention. As shown in FIG. 1, the IP telephone communication system 10 includes a SIP server 11, a PDSN (Packet Data Serving Node) 12a, a network (communication network) including a gateway 13, and a SIP server 11, PDSN 12b, and gateway 13. A mobile communication terminal (for example, a mobile body such as a mobile phone) 100a and a mobile communication terminal 100b communicate with each other via a network.

PDSN 12a is connected to EV-DO base station 14a, PDSN 12b is connected to EV-DO base station 14b, and gateway 13 is connected to a wireless LAN (Local Area Network) AP (Access Point) 15.
Then, the mobile communication terminal 100a and the mobile communication terminal 100b perform VoIP (Voice over Internet Protocol) communication using EV-DO as a communication network (see FIG. 1). -Each other's IP address acquired in the DO network is registered. EV-DO is a mobile communication standard dedicated to high-speed data communication based on CDMA2000.

FIG. 2 is a block diagram showing a configuration of the mobile communication terminal of FIG. As shown in FIG. 2, the mobile communication terminal 100 includes a transmission / reception unit 16, a handoff control unit 17, a data input / output control unit 18, a SIP control unit 19, an RTP (Real time Transport Protocol) packet unit 20, a video / audio unit 21, And a storage unit 22.
The transmission / reception unit 16 includes an EV-DO reception unit 23a and an EV-DO transmission unit 23b corresponding to EV-DO, and a wireless LAN reception unit 24a and a wireless LAN transmission unit 24b corresponding to the wireless LAN. The transmission / reception unit 16 is connected to an antenna 23c for EV-DO and an antenna 24c for wireless LAN.

The RTP packet unit 20 includes an RTP packet creation unit 20a and an RTP packet decoding unit 20b. The video / audio unit 21 includes a video input unit 25a such as a camera, a video output unit 25b such as an LCD, an audio input unit 26a such as a microphone, and an audio output unit 26b such as a speaker.
The RTP packet creation unit 20 a encodes signals from the video input unit 25 a and the audio input unit 26 a to create an RTP packet, and transmits data to the data input / output control unit 18. The RTP packet decoding unit 20b decodes the RTP packet received by the data input / output control unit 18, and transmits a signal to the video output unit 25b and the audio output unit 26b.
The handoff control unit 17 controls handoff between the EV-DO and the wireless LAN. The data input / output control unit 18 controls the transmission and reception of SIP and RTP packets using the EV-DO antenna 23c and the wireless LAN antenna 24c. The SIP control unit 19 analyzes the SIP message received by the data input / output control unit 18 and creates a SIP message.

  The storage unit 22 includes an EV-DO address storage unit 22a, a wireless LAN address storage unit 22b, a current host address storage unit 22c, a next host address storage unit 22d, a current partner address storage unit 22e, a next partner address storage unit 22f, and a switch. It has a timing storage unit 22g. The EV-DO address storage unit 22a stores an IP address used in EV-DO, and the wireless LAN address storage unit 22b stores an IP address used in the wireless LAN. The current address storage unit 22c stores the IP address currently used, and the next address storage unit 22d holds the IP address to be used after switching the communication path. The current partner address storage unit 22e stores the IP address of the partner currently in use, and the next partner address storage unit 22f holds the IP address of the partner used by the partner terminal after switching the communication path. The switching timing storage unit 22g stores the switching timing of communication path switching.

FIG. 3 is a block diagram showing the configuration of the SIP server of FIG. As shown in FIG. 3, the SIP server A is connected to a data transmission / reception unit 27 and a data transmission / reception unit 27 that transmit / receive signals to / from a mobile communication terminal 100 such as a mobile phone, for example, via a communication interface 27a. A transmission circuit unit (notification unit) 28, a reception circuit unit (reception unit) 29, a storage unit 30 for storing data to be processed in the SIP server A, a transmission circuit unit 28, a reception circuit unit 29, and a storage unit 30. A control unit (control means) 32 that is connected via the bus 31 and controls the operation in the SIP server A is provided.
Next, switching of communication paths in the IP telephone communication system according to the first embodiment of the present invention will be described.

Since the mobile communication terminal 100b (see FIG. 1) in communication with the mobile communication terminal 100a finds the wireless LAN AP 15 and acquires a new IP address in the wireless LAN network, the mobile communication terminal 100b switches to the wireless LAN. Reception level detection (RSSI) for measuring the strength is performed. When the electric field strength of the wireless LAN exceeds a certain threshold value, an extended SIP message “IPCHANGE” for switching the communication path to the wireless LAN network is created.
FIG. 4 is a sequence diagram showing exchange of SIP messages in communication path switching. 5 shows an example (part 1) of the SIP message of FIG. 101 is an explanatory diagram of FIG. 102 is an explanatory diagram of (102) Seq. FIG. FIG. 6 shows an example (part 2) of the SIP message of FIG. 104 is an explanatory diagram of (104) Seq. FIG. 105-1 is an explanatory diagram of (S). It is explanatory drawing of 105-2. Seq. Represents a sequence number.

As shown in FIGS. 4, 5, and 6, the mobile communication terminal 100 b transmits the created extended SIP message “IPCHANGE” to the SIP server 11 via the EV-DO network (FIGS. 4, 101, 5 (a)). )reference). Note that the three-digit numbers (101 to 111) in () and in the figure represent a sequence number.
The SIP server 11 transmits an extended SIP message “IPCHANGE” for switching the communication path to the mobile communication terminal 100a (see FIGS. 4, 102 and 5B). When the portable communication terminal 100a receives the message “IPCHANGE”, it returns a message “200 OK” indicating that it has been received to the SIP server 11 (see FIGS. 4, 103 and 5C).
The SIP server 11 that has received the message “200 OK” from the mobile communication terminal 100 a returns a message “200 OK” indicating that the mobile communication terminal 100 a has received the message “IPCHANGE” to the mobile communication terminal 100 b (FIG. 4). 104, see FIG. 6 (d)).

Thereafter, the SIP server 11 transmits an extended SIP message “CHANGEGETING” indicating the communication network switching timing of the mobile communication terminal 100b to the mobile communication terminal 100b (see FIGS. 4, 105-1 and 6 (e)), and at the same time. And transmitted to the mobile communication terminal 100a (see FIGS. 4, 105-2 and FIG. 6 (f)). At this time, it transmits to the portable communication terminal 100b using an EV-DO network.
When both the mobile communication terminal 100a and the mobile communication terminal 100b reach the time designated in the extended SIP message “CHANGEGETING”, that is, the time to perform handoff (FIG. 4, 106), the IP address of the mobile communication terminal 100b Is switched from the IP acquired in the EV-DO network to the IP acquired in the wireless LAN network (FIGS. 4 and 107), and communication is resumed (FIGS. 4 and 108). In the mobile communication terminal 100b, when the network switching is completed, the EV-DO side that is no longer used is disconnected or placed in the dormant state.

Next, the procedure of the communication path switching process will be described in detail.
First, the communication path switching side, that is, the communication path switching instruction transmission side will be described.
FIG. 7 is a flowchart showing a processing procedure of the mobile communication terminal on the communication path switching side. As shown in FIG. 7, first, the mobile communication terminal 100 on the communication path switching instruction transmission side determines whether or not VoIP communication is in progress (step (hereinafter abbreviated as S) 101). As a result of the determination, if VoIP communication is in progress (YES), loop processing is started (S102), and if VoIP communication is not in progress (NO), the determination is repeated.

By starting the loop process, the mobile communication terminal 100 that is performing VoIP communication performs a new network detection process for searching for a new network (in this example, a wireless LAN) (S103), and then determines whether or not to switch the communication path. Is determined (S104). As a result of the determination, if it is a communication path switching determination (YES), a communication path switching process is performed (S105), and if it is not a communication path switching determination (NO), the loop process is terminated as it is (S106), and the communication ends. Repeat the loop processing (S102 to S106). That is, when the communication path switching determination (S104) is not performed, the new network detection process (S103) and the communication path switching determination process (S104) are repeatedly performed until the communication ends.
Thereafter, the process ends. The details of the new network detection and communication path switching processing procedures will be described later.

FIG. 8 is a flowchart showing a new network detection processing procedure. As shown in FIG. 8, in the new network detection process (see FIG. 7, S103), the mobile communication terminal 100 first determines whether EV-DO communication is in progress (S201). As a result of the determination, if EV-DO communication is being performed (YES), a wireless LAN search is started (S202), and if EV-DO communication is not being performed (NO), the process is terminated.
It is determined whether or not a wireless LAN AP is found by wireless LAN search (S202) (S203). If the wireless LAN AP is found as a result of the determination (YES), the mobile communication terminal 100 An IP address is acquired in the network, and is input and stored in the wireless LAN address storage unit 22b (S204). After the acquired IP address is stored in the wireless LAN address storage unit 22, preparation for switching the communication path (S205) is performed, and then the process ends. On the other hand, if the result of determination in S203 is that a wireless LAN AP cannot be found (NO), the processing ends.

FIG. 9 is a flowchart showing a processing procedure for communication path switching preparation. As shown in FIG. 9, the mobile communication terminal 100 determines whether or not the electric field strength of the AP of the wireless LAN is equal to or higher than a threshold in the communication path switching preparation process (see S205 in FIG. 8) (S301). As a result of the determination, if the electric field strength is greater than or equal to the threshold (YES), the data of the wireless LAN address storage unit 22b is input to the next self address storage unit 22d (S302). On the other hand, if the electric field strength is not greater than or equal to the threshold (NO), the determination is repeated.
After the data of the wireless LAN address storage unit 22b is input to the next address storage unit 22d, an extended SIP message “IPCHANGE” is created (S303), and the created extended SIP message “IPCHANGE” is transmitted (S304). After the transmission, it is determined whether or not the message “200 OK” has been received (S305). If received (YES), the process is terminated, and if not received (NO), the determination is repeated.

  FIG. 10 is a flowchart showing a processing procedure of communication path switching determination. As shown in FIG. 10, the mobile communication terminal 100 determines whether or not the extended SIP message “CHANGEGETING” is received in the communication path switching determination process (see S104 in FIG. 7) (S401). If the extended SIP message “CHANGEGETING” is received as a result of the determination (YES), the switching time included in the message is input to the switching timing storage unit 22g (S402). After the switching time is input to the switching timing storage unit 22g, in the determination of whether or not to switch the communication path (see S104 in FIG. 7), the communication path is switched (YES) (S403). On the other hand, if it is determined in S401 that the message has not been received (NO), the process ends.

FIG. 11 is a flowchart illustrating a processing procedure for switching communication paths. As shown in FIG. 11, the mobile communication terminal 100 determines whether or not it is time to perform communication path switching in the communication path switching process (see S <b> 105 in FIG. 7) (S <b> 501). That is, it waits until the time stored in the switching timing storage unit 22g is reached. As a result of the determination, if the time has come (YES), it is determined whether or not the address is stored in the next address storage unit 22d (S502). On the other hand, if the time has not come (NO), the determination is made. repeat.
If the result of determination in S502 is that the next address storage unit 22d has an address (YES), the address stored in the current address storage unit 22c is changed to the address stored in the next address storage unit 22d. After the change (S503), the address stored in the next address storage unit 22d is discarded (erased) (S504), and then the process ends. On the other hand, if the next address storage unit 22d does not contain an address (NO), it is ERROR and the process is terminated without doing anything.

Next, the communication path switching instruction receiving side will be described.
FIG. 12 is a flowchart showing a processing procedure of the mobile communication terminal on the communication path switching instruction receiving side. As shown in FIG. 12, first, the mobile communication terminal 100 on the communication path switching instruction receiving side determines whether or not VoIP communication is in progress (S601). If the result of determination is that VoIP communication is in progress (YES), loop processing is started (S602), and if VoIP communication is not in progress (NO), the determination is repeated.
By starting the loop process, the mobile communication terminal 100 that is performing VoIP communication determines whether or not it is a communication path switching determination (S603). If it is determined that the communication path is switched (YES), the communication path is switched (S604). On the other hand, if the communication path switching is not determined (NO), the loop process is terminated (S605). The loop processing (S602 to S605) is repeated until the end of communication. Thereafter, the process ends. Details of the communication path switching processing procedure will be described later.

  FIG. 13 is a flowchart illustrating a processing procedure of communication path switching determination on the switching instruction receiving side. As shown in FIG. 13, first, the mobile communication terminal 100 determines whether or not the extended SIP message “IPCHANGE” is received in the communication path switching determination process (see FIG. 12, S603) (S701). As a result of the determination, when the extended SIP message “IPCHANGE” is received (YES), the address written in the message is input to the next partner address storage unit 22f (S702). On the other hand, if the message has not been received (NO), the process ends.

After the address is input to the next partner address storage unit 22f, the message “200 OK” is transmitted (S703). After the transmission, it is determined whether or not the extended SIP message “CHANGEGETING” has been received (S704). If the message is received as a result of the determination (YES), the switching time included in the message is input to the switching timing storage unit 22g (S705), and whether or not the communication path is switched after the input (FIG. 5) 12 (see S603), the communication path is set to be switched (YES) (S706), and then the process ends.
On the other hand, if the result of determination in S704 is that the extended SIP message “CHANGEGETING” has not been received (NO), the processing ends.

FIG. 14 is a flowchart illustrating a processing procedure for switching communication paths on the switching instruction receiving side. As illustrated in FIG. 14, the mobile communication terminal 100 determines whether or not it is time to perform communication path switching in the communication path switching process (see S604 in FIG. 12) (S801). That is, it waits until the time stored in the switching timing storage unit 22g is reached. As a result of the determination, if the time has come (YES), it is determined whether or not an address is stored in the next-party address storage unit 22f (S802). On the other hand, if the time has not come (NO), the determination is made. repeat.
If the result of determination in S802 is that an address is entered (YES), the address stored in the current partner address storage unit 22e is changed to the address stored in the next partner address storage unit 22f (S803), and after the change Then, the address stored in the next-party address storage unit 22f is discarded (erased) (S804), and then the process ends.

On the other hand, if the result of determination in S802 is that there is no address (NO), it is ERROR and the process is terminated as it is.
In this example, the IP address update notification message “IPCHANGE” and the IP address switching timing notification message “CHANGEGETING” are newly added, but a field necessary for this may be added to the existing message. The IP address switching timing notification message is transmitted by the SIP server, but may be issued from the portable communication terminal 100 on the IP address switching side or the portable communication terminal 100 on the switched side.
(Second Embodiment)

Next, switching of communication paths in the IP telephone communication system according to the second embodiment of the present invention will be described. Here, the existing SIP message “UPDATE” is used instead of the extended SIP message “IPCHANGE” in the first embodiment.
The configuration and operation of the IP telephone communication system and the mobile communication terminal according to the second embodiment are the same as the configuration and operation of the IP telephone communication system and the mobile communication terminal according to the first embodiment (see FIGS. 1 and 2). It is.

FIG. 15 is a sequence diagram showing exchange of SIP messages in communication path switching. 16 shows an example (part 1) of the SIP message of FIG. 201 is an explanatory diagram of FIG. 202 is an explanatory diagram of FIG. FIG. 17 shows an example (part 2) of the SIP message in FIG. 204 is an explanatory view of Seq. The explanatory diagram of 205-1, (f) is Seq. It is explanatory drawing of 205-2. Seq. Represents a sequence number.
Further, the process in which the mobile communication terminal 100b (see FIG. 1) communicating with the mobile communication terminal 100a creates the SIP message “UPDATE” for switching the communication path to the wireless LAN network is the extended SIP of the first embodiment. This is the same as the process for creating the message “IPCHANGE”.

As shown in FIGS. 15, 16, and 17, the mobile communication terminal 100 b transmits an existing SIP message “UPDATE” to the SIP server 11 via the EV-DO network (FIGS. 15, 201, and 16 (a)). reference). In the SIP message, the content (body) of “Contact: ˜” is attached to the Content-Type together with the new media type “application / ipchange” (see the underline in the figure). Note that the three-digit numbers (201 to 206) in () and in the figure represent a sequence number.
The SIP server 11 transmits a SIP message “UPDATE” for switching the communication path to the mobile communication terminal 100a (see FIGS. 15 and 202 and FIG. 16B). When the mobile communication terminal 100a receives the message “UPDATE”, it returns a message “200 OK” indicating that it has been received to the SIP server 11 (see FIGS. 15, 203, and 16C).

The SIP server 11 that has received the message “200 OK” from the mobile communication terminal 100 a returns a message “200 OK” indicating that the mobile communication terminal 100 a has received the message “UPDATE” to the mobile communication terminal 100 b (FIG. 15). 204, FIG. 17 (d)).
Thereafter, the SIP server 11 transmits an extended SIP message “UPDATE” indicating the switching timing of the communication network of the mobile communication terminal 100b to the mobile communication terminal 100b (see FIGS. 15 and 205-1 and FIG. 17E). And transmitted to the mobile communication terminal 100a (see FIGS. 15, 205-2, and FIG. 17 (f)). At this time, it transmits to the portable communication terminal 100b using an EV-DO network.

  Then, when both the mobile communication terminal 100a and the mobile communication terminal 100b come to the time designated in the SIP message “UPDATE”, that is, the time to perform handoff (FIGS. 15 and 206), the IP address of the mobile communication terminal 100b is changed. Then, the IP acquired by the EV-DO network is switched to the IP acquired by the wireless LAN network (FIGS. 15 and 207), and communication is resumed (FIGS. 15 and 208). In the mobile communication terminal 100b, when the network switching is completed, the EV-DO side that is no longer used is disconnected or placed in the dormant state.

  As described above, the wireless communication terminal (100b) acquires the IP address from the first wireless communication system (EV-DO communication network), and uses the first wireless communication system using the acquired IP address. An IP address is acquired from the first wireless communication means (EV-DO receiving unit 23a, EV-DO transmitting unit 23b) for performing communication and the second wireless communication system (wireless LAN network), and the acquired IP address is A second wireless communication means (wireless LAN receiver 24a, wireless LAN transmitter 24b) that performs communication using the second wireless communication system, and a partner wireless communication terminal (100a) that performs call connection using SIP Is switched from the first wireless communication means to the second wireless communication means when the IP address acquired from the first wireless communication system is used via the first wireless communication means. If it is determined that the communication is performed, a SIP message is used to change the IP address acquired from the second wireless communication system by the second wireless communication means to the partner wireless communication terminal (100a) of the communication. Control means (hand-off control unit 17, SIP control unit 19) for controlling to notify the user.

This control means notifies the change to the IP address acquired from the second wireless communication system to the SIP server 11 that performs call control using the SIP message, and the IP address acquired from the SIP server 11 in response to the notification. Based on the change time, the IP address acquired from the first wireless communication system is changed to the IP address acquired from the second wireless communication system, and the changed IP address is used to change the IP address via the second wireless communication means. Control to perform communication.
In addition, when the control unit detects that the received electric field strength of the second wireless communication system exceeds a predetermined value, the control unit determines to perform communication by switching from the first wireless communication unit to the second wireless communication unit. In addition, when the communication with the partner mobile communication terminal that has performed the call control using the SIP is performed via the first wireless communication unit using the IP address acquired from the first wireless communication system, the second When the wireless communication system has not been detected, the second wireless communication means is controlled to search for the second wireless communication system.

The second wireless communication system preferably has a higher maximum system throughput than the first wireless communication system.
In addition, the wireless communication terminal (100b) describes and describes the IP address acquired from the second wireless communication system in a message (UPDATE) notifying update of media negotiation by SDP (Session Description Protocol). SDP is a protocol that carries media information (control of multimedia sessions). Thereby, switching of the wireless communication network can be realized with an existing message.
Although the present invention has been described with reference to the above-described embodiment, it is not limited to this embodiment. Therefore, what is implemented as a change aspect without deviating from the meaning of the present invention is also included.

It is explanatory drawing which shows notionally the IP telephone communication system which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structure of the portable communication terminal of FIG. It is a block diagram which shows the structure of the SIP server of FIG. It is a sequence diagram which shows the exchange of the SIP message in communication path switching. 4 shows an example (part 1) of the SIP message of FIG. 101 is an explanatory diagram of FIG. 102 is an explanatory diagram of (102) Seq. FIG. 4 shows an example (part 2) of the SIP message in FIG. 104 is an explanatory diagram of (104) Seq. FIG. 105-1 is an explanatory diagram of (S). It is explanatory drawing of 105-2. It is a flowchart which shows the process sequence of the portable communication terminal by the side of communication path switching. It is a flowchart which shows the process sequence of a new network detection. It is a flowchart which shows the process sequence of communication path | route switching preparation. It is a flowchart which shows the process sequence of communication path switching determination. It is a flowchart which shows the process sequence of communication path switching. It is a flowchart which shows the process sequence of the mobile communication terminal by the side of communication path switching instruction | indication reception. It is a flowchart which shows the process sequence of the communication path switching determination in the switching instruction | indication receiving side. It is a flowchart which shows the process sequence of the communication path switching in the switching instruction | indication receiving side. It is a sequence diagram which shows the exchange of the SIP message in communication path switching. FIG. 15 shows an example (part 1) of the SIP message in FIG. 201 is an explanatory diagram of FIG. 202 is an explanatory diagram of FIG. FIG. FIG. 15 shows an example (part 2) of the SIP message in FIG. 204 is an explanatory view of Seq. 205 is an explanatory diagram of (205), Seq. 206 is an explanatory diagram of FIG. It is explanatory drawing which shows the conventional IP telephone communication system notionally. FIG. 19 is a sequence diagram for explaining a call by the IP telephone communication system of FIG. 18. It is explanatory drawing which shows notionally other conventional IP telephone communication systems. It is explanatory drawing which shows notionally the case where mobile communication is used in the IP telephone communication system of FIG.

Explanation of symbols

10 IP telephone communication system 11 SIP server 12a, 12b PDSN
13 Gateway 14a, 14b EV-DO base station 15 Wireless LAN AP
16 Transmission / Reception Unit 17 Handoff Control Unit 18 Data Input / Output Control Unit 19 SIP Control Unit 20 RTP Packet Unit 20a RTP Packet Creation Unit 20b RTP Packet Decoding Unit 21 Video / Audio Unit 22, 30 Storage Unit 22a EV-DO Address Storage Unit 22b Wireless LAN Address storage unit 22c Current host address storage unit 22d Secondary host address storage unit 22e Current partner address storage unit 22f Next partner address storage unit 22g Switching timing storage unit 23a EV-DO reception unit 23b EV-DO transmission unit 23c, 24c Antenna 24a Wireless LAN receiver 24b Wireless LAN transmitter 25a Video input unit 25b Video output unit 26a Audio input unit 26b Audio output unit 27 Data transmission / reception unit 27a Communication interface 28 Transmission circuit unit 29 Reception circuit unit 31 Bus 32 Control unit 100a mobile communication terminal 100b mobile communication terminal

Claims (6)

First wireless communication means for acquiring an IP address from the first wireless communication system and performing communication using the first wireless communication system using the acquired IP address;
Second wireless communication means for acquiring an IP address from the second wireless communication system and performing communication using the second wireless communication system using the acquired IP address;
When communication with a partner terminal that has made a call connection using SIP (Session Initiation Protocol) is performed via the first wireless communication means using the IP address acquired from the first wireless communication system, When it is determined that the communication is performed by switching from the first wireless communication unit to the second wireless communication unit, the IP acquired from the second wireless communication system by the second wireless communication unit to the partner terminal of the communication Control means for controlling the notification to change to an address using a SIP message;
A wireless communication terminal comprising:   The control means notifies the change to the IP address acquired from the second wireless communication system to the SIP server that performs call control using a SIP message, and the IP address change acquired from the SIP server in response to the notification Based on the time, the IP address acquired from the first wireless communication system is changed to the IP address acquired from the second wireless communication system, and the changed IP address is used to pass through the second wireless communication means. The wireless communication terminal according to claim 1, wherein the wireless communication terminal is controlled to perform the communication.   When the control means detects that the received electric field strength of the second wireless communication system exceeds a predetermined value, the control means determines to switch from the first wireless communication means to the second wireless communication means to perform the communication. The wireless communication terminal according to claim 1, wherein the wireless communication terminal is a wireless communication terminal.   When the control means is performing communication with the counterpart terminal that has performed call control using the SIP via the first wireless communication means using the IP address acquired from the first wireless communication system. 4. When the second wireless communication system is not detected, the second wireless communication means controls to search the second wireless communication system. The wireless communication terminal described in 1.   The wireless communication terminal according to any one of claims 1 to 4, wherein the second wireless communication system has a maximum system throughput higher than that of the first wireless communication system.   6. An IP address acquired from the second wireless communication system is described in a message (UPDATE) for notifying an update of media negotiation by SDP (Session Description Protocol), and notified. The wireless communication terminal according to one item.

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