JP2011171779A - Femtocell system, gateway device and method of handover between circuit exchange network which is used for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a femtocell system capable of achieving handovers between a device under the control of an IMS (IP multimedia subsystem)/MMD (multimedia domain) system and a device under the control of a circuit exchange network. <P>SOLUTION: The femtocell system adopts an IMS/MMD connection method that integrates the call process into the IMS/MMD. In addition, the femtocell system has: a first gateway device for exchanging the call process signals with an MSC (mobile switching center), which performs the handover process of a mobile terminal under the control of the circuit exchange network; and a second gateway device that connects an audio path to the MSC. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a femtocell system, a gateway device, and a handover method between circuit-switched networks used for them, and more particularly, to a femtocell system of an IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain) connection method.

  In the femtocell system, “expanding low-cost areas in indoor insensitive areas such as high-rise condominiums and basements” and “using a broadband line for the access line of the femtocell system, combined FMC (Fixed Mobile) Introduction of mobile operators is under study for the purpose of “deploying services” and “suppressing capital investment of macro base stations by diverting indoor data traffic to the femtocell system”.

  As a method for realizing a femto cell system, a method of arranging Femto-AP (Access Point) under the control of RNC (Radio Network Controller), a method of arranging Femto-AP under the control of Mobile Switching Center (MSC), and Femto-AP There are multiple implementation methods, such as a method of directly connecting to IMS / MMD.

  An operator who has already introduced IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain), or an operator who is considering introducing IMS / MMD in the future, integrates the call processing of the femtocell system into IMS / MMD. Future capital investment can be reduced.

  Regarding IMS / MMD, there is a technique described in Patent Document 1 below. Patent Document 1 describes a P-CSCF (Proxy Call Session Control Function) high-speed handoff for an IMS / MMD architecture.

  An outline of the IMS / MMD type femtocell network is shown in FIG. On the circuit switching network 300 side, there is an MS (Mobile Station: terminal) 1 under the circuit switching network. As the configuration nodes of the circuit switching network 300, there are an RNC / base station 2 that is a RAN (Radio Access Network) side device, an MSC 3 that is a core side node, and a GS (Gateway MSC) 4 that is a gate for connection to another network. And HLR (Home Location Register) / HSS (Home Subscriber Server) 5 for managing subscriber data.

  Further, as a node constituting the IMS / MMD type femtocell system, the MS 6 exists under the Femto, and the Femto-AP 7 converts the call processing signal of the circuit switching network 300 from the MS 6 into a SIP (Session Initiated Protocol) signal. Is placed.

  Between the Femto-AP 7 and the PDG (Packet Date Gateway) / AGW (Access Gateway) 8, an IPsec (Internet Protocol security protocol) tunnel is established to ensure security, and the IMS / MMD network 400 is established through the established IPsec tunnel. Connect to.

  The IMS / MMD network 400 includes a CSCF (Call Server Control Function) 9 that performs call processing, an AS (Application Server) 10 that performs service control of additional services, and an MGCF (Media Gateway Control) that serves as a gate for connecting to other networks. Function) / IM-MGW (IP Multimedia MGW) 11 and HLR / HSS 5 for managing subscriber data.

  Here, the RNC / base station 2 is generally separated into an RNC and a base station and is arranged in a network. The HLR / HSS 5 is described as a degenerate configuration of the HLR function and the HSS function. However, depending on the network, there are cases where the HLR exists in the circuit switching network 300 and the HSS exists in the IMS / MMD network 400.

  The network shown in FIG. 12 enables communication between MS1 under the circuit switching network and MS6 under the Femto. FIG. 13 shows a conduction example of the C-Plane signal (signal) and U-Plane data (voice) used for call processing. FIG. 13 shows an outline of communication between the IMS / MMD circuit switching network and the femtocell.

  In this case, the signal is connected through each device of MS1, RNC / base station 2, MSC3, GS4, MGCF / IM-MGW11, CSCF9, AS10, PDG / AGW8, Femto-AP7, and MS6. Also, the voice is connected through each device of MS1, RNC / base station 2, MSC3, GS4, MGCF / IM-MGW11, PDG / AGW8, Femto-AP7, and MS6.

JP 2008-072687 A

  The above-described method in which the Femto-AP is directly connected to the IMS / MMD (IMS / MMD method) has the following problems. That is, the network configuration shown in FIG. 12 has a problem in handover between the circuit switching network and the femtocell.

  For the handover between the circuit switching network 300 and the femtocell network 200, studies are underway to perform handover control in the AS 10 in the IMS / MMD network 400. However, functions are added to the node on the circuit switching network 300 side. It is essential and the handover between the existing circuit switching network 300 and the femtocell network 200 cannot be realized.

  The above-mentioned Patent Document 1 describes P-CSCF high-speed handoff, but does not describe handover between a circuit-switched network and a femtocell network, and cannot solve the above problem.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to solve the above-described problems and realize a handover between a subordinate of the IMS / MMD type femtocell system and a subordinate of the circuit switching network, a gateway device, and a line used for the same. It is to provide a method for handover between switching networks.

A femtocell system according to the present invention is a femtocell system that employs an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain).
A first gateway device that exchanges call processing signals with an MSC (Mobile Switching Center) that performs handover processing of a mobile terminal under a circuit switching network, and a second gateway that connects a voice path with the MSC Device.

A gateway device according to the present invention is a gateway device used in a femtocell system that employs an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain).
A first means for exchanging a call processing signal with a mobile switching center (MSC) that performs a handover process for a mobile terminal under a circuit switched network, and another gateway device for connecting a voice path with the MSC. Second means for controlling.

A handover method between circuit-switched networks according to the present invention is a handover method between circuit-switched networks used in a femtocell system that employs an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain). And
The first gateway device exchanges call processing signals with an MSC (Mobile Switching Center) that performs handover processing of mobile terminals under the circuit switching network,
A voice path is connected to the MSC at the second gateway device.

  By adopting the above-described configuration and operation, the present invention can achieve an effect that a handover between an IMS / MMD type femtocell system and a circuit switched network can be realized.

  Next, embodiments of the present invention will be described with reference to the drawings. First, an outline of the femtocell system according to the present invention will be described. The femtocell system according to the present invention is configured with a femto-GW (Femto Gateway) and a femto-MGW (Femto Media Gateway) IMS (IP Multimedia Subsystem) system and a MMD (MultiMedia Domain) network femto system. Provides a handover method between subordinates.

  FIG. 1 is a diagram showing a network outline of an IMS / MMD type femtocell system after introducing Femto-GW and Femto-MGW according to the present invention. In FIG. 1, Femto-GW 12 and Femto-MGW 13 are connected to Femto-AP (Femto Access Point) 7 via PDG (Packet Data Gateway) / AGW (Access Gateway) 8 and IMS / MMD core network, respectively. To send and receive call processing signals and voice data.

  In addition, the Femto-GW 12 is also connected to an MSC (Mobile Switching Center) 3 that is a core node of the circuit switching network 300 to realize a handover process. Thereby, in the present invention, the above-mentioned problem can be solved.

  In the present invention, the network shown in FIG. 1 enables communication between an MS (Mobile Station) 1 under the circuit switching network and an MS 6 under the Femto.

  FIG. 2 is a diagram showing an outline of communication between the IMS / MMD type femtocell network 200 and the circuit switching network 300 after the introduction of the Femto-GW 12 and the Femto-MGW 13 of FIG. FIG. 2 shows a conduction example between a C-Plane signal (signal) and U-Plane data (voice) used for call processing.

  Signals are MS1, RNC / base station 2, MSC3, GS (Gateway MSC) 4, MGCF (Media Gateway Control Function) / IM-MGW (IP Multimedia MGW) 11, CSCF (Call Server Control AF). Server) 10, Femto-GW12, PDG / AGW8, Femto-AP7, and MS6.

  The voice is connected through each device of MS1, RNC / base station 2, MSC3, GS4, MGCF / IM-MGW11, Femto-MGW13, PDG / AGW8, Femto-AP7, and MS6.

  During the handover process, the Femto-GW 12 communicates with the MSC 3 which is a node on the circuit switching network 300 side, exchanges information necessary for the handover, and controls the Femto-MGW 13 so that the Femto-MGW 13 and the MSC 3 Set the audio path.

  Therefore, according to the present invention, it is possible to perform handover with the circuit switched network 300 even though the femtocell system adopts the IMS / MMD connection method in which call processing is integrated into IMS / MMD.

  The network outline of the femtocell system according to the first embodiment of the present invention is the network of the femtocell system of the IMS / MMD system after introducing the Femto-GW and Femto-MGW according to the present invention shown in FIG. The outline is the same.

  The circuit switching network 300 side has the same configuration as that of FIG. 12, and the MS 1 exists under the circuit switching network. The circuit switching network 300 includes the following nodes: RNC / base station 2 that is a RAN (Radio Access Network) side device, MSC 3 that is a core side node, GS4 that serves as a gate for connection to other networks, and subscriber data. HLR (Home Location Register) / HSS (Home Subscriber Server) 5 exists.

  Further, as a node constituting the IMS / MMD type femtocell system, the MS 6 exists under the Femto, and the Femto-AP 7 converts the call processing signal of the circuit switching network 300 from the MS 6 into a SIP (Session Initiated Protocol) signal. Is placed.

  Between the Femto-AP 7 and the PDG / AGW 8, an IPsec (Internet Protocol security protocol) tunnel is established to ensure security, and the IMS / MMD network 400 is connected through the established IPsec tunnel.

  In the present embodiment, Femto-GW 12 and Femto-MGW 13 are newly introduced at the entrance of IMS / MMD network 400 to simulate a SIP terminal viewed from IMS / MMD network 400. The Femto-GW 12 and the Femto-MGW 13 are also connected to the MSC 3 that is a node on the circuit switching network 300 side.

  Similarly to FIG. 12, the IMS / MMD network 400 has a CSCF 9 that performs call processing, an AS 10 that performs service control of additional services, an MGCF / IM-MGW 11 that serves as a gate for connection to other networks, and subscriber data. There is an HLR / HSS5 to be managed.

  Here, the RNC / base station 2 is generally separated from the RNC and the base station and arranged in the network. Moreover, although HLR / HSS5 is described as a degenerate configuration of the HLR function and the HSS function, depending on the network, there are cases where the HLR exists in the circuit switching network 300 and the HSS exists in the IMS / MMD network 400, respectively. .

  Further, the Femto-AP 7 has a function of converting the call processing signal of the circuit switching network 300 from the MS 6 into a SIP signal. However, the interface with the Femto-GW 12 is not limited to the SIP, and the Femto-GW 12 uses the SIP. It may be converted into a signal.

  FIG. 3 is a block diagram showing a configuration example of the Femto-GW 12 according to the first embodiment of the present invention. 3, the Femto-GW 12 includes an IMS / MMD connection unit 121, a media control unit 122, a handover control unit 123, and an authentication / location registration unit 124.

  The IMS / MMD connection unit 121 holds a SIP protocol function for connecting to the IMS / MMD, and simulates a SIP terminal viewed from the IMS / MMD network 400. Further, the media control unit 122 controls the Femto-MGW 13 using, for example, a MEGACO (Media Gateway Control Protocol) protocol for media control.

  Further, the handover control unit 123 holds a circuit switched network protocol function such as MAP (Mobile Application Part) with the MSC 3 on the circuit switched network 300 side for handover control. In addition to the above, the authentication / location registration unit 124 has a function of connecting to the HLR for authentication and location registration as the circuit switched network 300.

  FIG. 4 is a block diagram showing a configuration example of the Femto-MGW 13 according to the first embodiment of the present invention. In FIG. 3, the Femto-MGW 13 is located between the MS 6 and the IMS / MMD network 400, and includes a media conversion unit 131 and a handover processing unit 132.

  The media conversion unit 131 performs media conversion as necessary according to an instruction from the Femto-GW 12. The handover processing unit 132 also has a function of connecting the voice path with the MSC 3 on the circuit switched network 300 side according to an instruction from the Femto-GW 12 in the handover process.

  FIG. 5 is a diagram showing an overview of handover processing (processing before handover) in the circuit switched network 300 according to the first embodiment of the present invention, and FIG. 6 is a circuit according to the first embodiment of the present invention. FIG. 7 is a diagram showing an outline of handover processing (processing after handover) in the switching network 300, and FIG. 7 shows a femto cell after introducing Femto-GW 12 and Femto-MGW 13 according to the first embodiment of the present invention. It is a figure which shows the outline | summary of the hand-over process from a subordinate to a circuit switched network subordinate. A handover process in the first embodiment of the present invention will be described with reference to FIGS.

  In order to clarify the difference between the handover processing under the femtocell and the circuit switching network, first, the handover processing in the circuit switching network 300 is changed to the handover processing (before handover) in the circuit switching network 300 shown in FIG. And the outline of the handover process (after the handover) in the circuit switching network 300 shown in FIG.

  FIG. 5 is a connection image of the circuit switched network 300 before handover. There are two MS1a and MS1b under the circuit switching network, which are connected to MSC3a and MSC3b through RNC / base station 2a and RNC / base station 2b, respectively. When MSC3a and MSC3b are connected, call processing signals Audio data is conducted. The RNC / base station 2a, RNC / base station 2b or MSC 3a, MSC 3b may be the same RNC / base station and MSC depending on the position of the MS.

  Here, FIG. 6 shows the flow of signals and voices when the MS 1b located under the RNC / base station 2b moves under the RNC / base station 2a. When the RNC / base station 2b receives a notification to hand over from the MS 1b to the RNC / base station 2a, it requests the MSC 3b to perform a handover process. The MSC 3b performs a handover process with the MSC 3a that is the handover destination MSC.

  The call processing signal after the handover is not a connection from the MSC 3b to the RNC / base station 2b but a connection from the MSC 3b to the MSC 3a, and the voice path is also connected. The MSC 3a connects a voice path with the RNC / base station 2a, and the RNC / base station 2a connects a voice path with the MS 1b.

  Thus, in the present embodiment, the circuit switching network 300 is handed over by exchanging call processing signals between the MSCs 3a and 3b and connecting the voice paths. The process so far is an existing process.

  The implementation of handover between the IMS / MMD connection type femto cell system using the Femto-GW 12 and the Femto-MGW 13 and the circuit switched network 300 will be described.

  In the handover between the IMS / MMD connection type femto cell system using the Femto-GW 12 and the Femto-MGW 13 and the circuit switching network 300, the Femto-GW 12 and the Femto-MGW 13 have the MSC equivalent function of the circuit switching network 300. Holds to realize handover.

  FIG. 7 shows the flow of signals and voices when the MS 6 moves from the connection of FIG. 2 to the subordinate of the circuit switching network. FIG. 7 shows an outline of the handover process from the subordinate of the femto cell to the subordinate of the circuit switched network after the introduction of the Femto-GW 12 and the Femto-MGW 13.

  When the Femto-AP 7 receives notification from the MS 6 that the RNC / base station 2 is to be handed over, the Femto-AP 7 requests the Femto-GW 12 to perform handover processing through the PDG / AGW 8. The Femto-GW 12 performs a handover process using the protocol of the circuit switching network 300 with the MSC 3 that is the handover destination MSC.

  The call processing signal after the handover is not a connection from the Femto-GW 12 to the Femto-AP 7 through the PDG / AGW 8 but from the Femto-GW 12 to the MSC 3 and controls the Femto-MGW 13 to change the connection of the voice path. . The voice path is not a connection from the Femto-MGW 13 to the Femto-AP 7 through the PDG / AGW 8 but a connection from the Femto-MGW 13 to the MSC 3 under the control of the Femto-GW 12. The MSC 3 connects a voice path with the RNC / base station 2, and the RNC / base station 2 connects a voice path with the MS 6.

  As described above, the Femto-GW 12 exchanges a call processing signal with the MSC 3 and connects the voice path between the Femto-MGW 13 and the MSC 3 to realize the handover.

  FIG. 8 is a sequence chart showing an example of handover processing from a femto cell to a circuit switched network according to the first embodiment of the present invention. With reference to FIG. 8, the handover sequence from the above-described femtocell to the circuit-switched network will be described.

  FIG. 8 is a 3GPP2 (3rd Generation Partnership Project 2) -based sequence, and the protocol between the Femto-GW 12 and the MSC 3 is based on MAP defined by 3GPP2.

  As nodes that perform the handover process, there are Femto-AP7, Femto-GW12, and Femto-MGW13 as handover sources. Moreover, MSC3 and BSC (Base Station Center) which is a RAN side apparatus exist in a handover destination (Target).

  When the MS is handed over from a subordinate of a femtocell in which a session has been established to a subordinate of a circuit switched network, the MS notifies the Femto-AP7 that the handover is to be performed, and the Femto-AP7 uses SIP, for example, the “MESSAGE” method [MESSAGE ( Handoff Required)] is used to notify the Femto-GW 12 of the handover destination information (a1 in FIG. 8).

  When the Femto-GW 12 receives the SIP “MESSAGE”, the Femto-GW 12 returns a SIP “200 OK (MESSAGE)” (a2 in FIG. 8), and also uses the MEGACO “Add” signal (Add Req, Add Reply) for the Femto- The resources of the MGW 13 are secured (a3 and a4 in FIG. 8). Thereafter, the Femto-GW 12 transmits “FACDIR2” in which the resource information of the secured Femto-MGW13 is set to the Target MSC 3 (a5 in FIG. 8).

  The Target MSC 3 transmits a “HOREQ” to the subordinate BSC and performs a handover process (a6 in FIG. 8). Upon receiving “HOREQACK” from the BSC (a7 in FIG. 8), the MSC 3 returns “facdir2” in which the voice path connection destination information of the MSC 3 is set to the Femto-GW 12 (a8 in FIG. 8).

  Upon receiving “facdir2”, the Femto-GW 12 sets the connection information on the MSC3 side to the Femto-MGW13 by the MEGACO “Mod” signal (Add Req, Add Reply) (a9, a10 in FIG. 8), and the MSC3 Instructs to copy downstream audio data.

  When the connection of the voice path is completed, the Femto-GW 12 notifies the Femto-AP 7 that the handover process has been completed using “MESSAGE (Handoff Command)” of the SIP “MESSAGE” method (a11 in FIG. 8). When the Femto-AP 7 receives “MESSAGE (Handoff Command)”, the Femto-AP 7 returns SIP “200 OK (MESSAGE)” (a12 in FIG. 8).

  When Femto-GW 12 receives “MESSAGE (Handoff Commended)” of the SIP “MESSAGE” method of handover completion from Femto-AP 7 side (a 13 in FIG. 8), Femto-AP 7 receives SIP “200 OK (MESSAGE)”. Return it (a14 in FIG. 8). Thereafter, the Femto-GW 12 stops transmission of the downlink voice data to the Femto-AP 7 by the MEGACO “Mod” signal (Mod Req, Mod Reply) to the Femto-MGW 13 (a15 and a17 in FIG. 8).

  When the handover process on the BSC side is completed, the MSC 3 receives “HOCOMP” from the BSC (a 16 in FIG. 8), and notifies the Femto-GW 12 of the completion of the handover process with “MSONCH” (a 18 in FIG. 8).

  Upon receiving “MSONCH”, the Femto-GW 12 leaves the Femto-MGW 13 resources for handover, and deletes the Femto-MGW 13 resources with the Femto-AP 7 using the MEGACO “Sub” signal (Sub Req, Sub Reply). (A19, a20 in FIG. 8).

  Further, the Femto-GW 12 notifies the Femto-AP 7 of the completion of the handover process by “MESSAGE (Clear Command)” of the SIP “MESSAGE” method (a 21 in FIG. 8). When the Femto-AP 7 receives “MESSAGE (Clear Command)”, the Femto-AP 7 returns SIP “200 OK (MESSAGE) (Clear Complete)” (a22 in FIG. 8).

  Finally, the session established between the Femto-GW 12 and the Femto-AP 7 is deleted by the SIP “BYE” method (a23 and a24 in FIG. 8). As described above, the handover process is performed in the present embodiment.

  As described above, in the present embodiment, in the IMS / MMD type femtocell system, by using the Femto-GW12 and the Femto-MGW13, between the subordinate of the IMS / MMD type femtocell system and the subordinate of the circuit switching network. Handover can be realized, and even when the MS moves between the femtocell system and the circuit switching network 300, continuous communication can be performed in the MS.

  In the present invention, the handover from the subordinate of the femtocell to the subordinate of the circuit switched network is described as an example. However, the handover from the subordinate of the circuit switched network to the subordinate of the femtocell, or the handover between the subordinate of the femtocell and the subordinate of the femtocell is also possible. Is possible. In the present invention, the Femto-GW 12 and the Femto-MGW 13 are introduced to implement the handover process. However, the PDG / AGW 8 and the CSCF 9 can be used without newly introducing the Femto-GW 12 and the Femto-MGW 13. It is also possible to degenerate the functions of each of the Femto-GW 12 and the Fwto-MGW 13 in an existing apparatus such as the above.

  Furthermore, in the present invention, an example is described in which handover is performed with the MSC 3 on the circuit switched network 300 side, but there are also cases where the operator performs handover processing on the RAN side.

  In order to clarify the difference between the handover process under the femtocell and the circuit switching network, as an example of performing the handover process in the circuit switching network 300, FIG. 9 shows a handover process between the RNCs 3a and 3b (before the handover). FIG. 10 shows an overview of handover processing (processing after handover) between the RNCs 3a and 3b.

  FIG. 9 is a connection image of the circuit switching network 300 before handover. Two MS1a and MS1b exist under the circuit switching network, and are connected to MSC3a and MSC3b through RNC / base station 2a and RNC / base station 2b, respectively. In this case, the call processing signal and the voice data are conducted by connecting the MSC 3a and the MSC 3b. The RNC / base station 2a, RNC / base station 2b or MSC 3a, MSC 3b may be the same RNC / base station and MSC depending on the position of the MS.

  Here, FIG. 10 shows the flow of signals and voices when the MS 1b located under the RNC / base station 2b moves under the RNC / base station 2a. The RNC / base station 2b receives a notification to hand over from the MS 1b to the RNC / base station 2a. The RNC / base station 2b performs a handover process with the RNC / base station 2a, which is a handover destination RNC.

  The call processing signal after the handover is not a connection from the RNC / base station 2b to the MS 1b but a connection from the RNC / base station 2b to the RNC / base station 2a, and also connects a voice path. The RNC / base station 2a connects a voice path with the MS 1b.

  Thus, in the present invention, the handover is realized by exchanging call processing signals between the RNCs 3a and 3b and connecting the voice paths. The process so far is an existing process. Hereinafter, a handover process between the IMS / MMD connection type femtocell system and the RAN side apparatus of the circuit switching network 300 will be described.

  In order to realize handover between the femtocell system of the IMS / MMD connection method using the Femto-GW 12 and the Femto-MGW 13 and the RAN side device of the circuit switching network 300, the RNSAP (Radio Network Subsystem) is provided to the Femto-GW 12. The Femto-GW 12 has a circuit switching network protocol function for communicating with a RAN side device such as an Application Part), and the Femto-GW 12 communicates with the RNC / base stations 2a and 2b of the circuit switching network 300. The IMS / MMD type femtocell system and the circuit switching network 300 have the configuration shown in FIG. 11 as shown in the outline of the handover process from the subordinate to the femtocell subordinate to the circuit switching network after the introduction of the GW 12 and the Femto-MGW 13. R It becomes possible to realize a handover process between the N-side device.

  FIG. 11 shows a state in which handover has been performed with the RAN side device of the circuit switching network 300. When the MS 6 moves under the circuit switching network, the Femto-AP 7 receives a notification from the MS 6 that it will be handed over to the RNC / base station 2. The Femto-AP 7 requests the Femto-GW 12 for handover processing through the PDG / AGW 8.

  The Femto-GW 12 performs a handover process using the protocol of the circuit switched network 300 with the RNC / base station 2 that is the RNC of the handover destination. The call processing signal after the handover is not the connection from the Femto-GW 12 to the Femto-AP 7 through the PDG / AGW 8 but the connection from the Femto-GW 12 to the RNC / base station 2, and in order to change the connection of the voice path Control the MGW 13.

  The voice path is not a connection from the Femto-MGW 13 to the Femto-AP 7 through the PDG / AGW 8 but a connection from the Femto-MGW 13 to the RNC / base station 2 under the control of the Femto-GW 12. The RNC / base station 2 connects a voice path with the MS 6.

  As described above, in the present invention, the Femto-GW 12 exchanges call processing signals with the RNC, and the handover is realized by connecting the voice path between the Femto-MGW 13 and the RNC.

  The present invention is applicable to an operator who newly introduces a femtocell system, particularly an operator who holds an IMS / MMD system and an operator who will introduce IMS / MMD from now on. In the present invention, it is possible to provide handover with a circuit switched network while utilizing IMS / MMD.

It is a figure which shows the network outline | summary of the femtocell system of the IMS / MMD system after introducing Femto-GW and Femto-MGW by this invention. It is a figure which shows the communication outline | summary between the femtocell network of an IMS / MMD system after introducing Femto-GW and Femto-MGW of FIG. 1, and a circuit switching network. It is a block diagram which shows the structural example of Femto-GW by the 1st Embodiment of this invention. It is a block diagram which shows the structural example of Femto-MGW by the 1st Embodiment of this invention. It is a figure which shows the outline | summary of the hand-over process (process before a hand-over) in the circuit switching network by the 1st Embodiment of this invention. It is a figure which shows the outline | summary of the hand-over process (process after hand-over) in the circuit switching network by the 1st Embodiment of this invention. It is a figure which shows the outline | summary of the hand-over process from the subordinate of the femtocell to the subdivision of a circuit switched network after introducing Femto-GW and Femto-MGW by the 1st Embodiment of this invention. 6 is a sequence chart showing a processing example of handover from a femtocell subordinate to a circuit switched network subordinate according to the first exemplary embodiment of the present invention. It is a figure which shows the outline | summary of the hand-over process (process before a hand-over) between RNC by the 1st Embodiment of this invention. It is a figure which shows the outline | summary of the handover process (process after a hand-over) between RNCs between RNC by the 1st Embodiment of this invention. It is a figure which shows the outline | summary of the hand-over process from the subordinate of a femtocell to a subdivision of a circuit switched network after introducing Femto-GW and Femto-MGW with the RNC function by this invention. It is a figure which shows the outline | summary of the femtocell network of the IMS / MMD system relevant to this invention. It is a figure which shows the outline | summary of the communication between the circuit switching network of the IMS / MMD system relevant to this invention, and a femtocell.

Explanation of symbols

1,1a, 1b, 6 MS
2, 2a, 2b RNC / base station 3, 3a, 3b MSC
4 GS
5 HLR / HSS
7 Femto-AP
8 PDG / AGW
9 CSCF
10 AS
11 MGCF / IM-MGW
12 Femto-GW
13 Femto-MGW
100 public network
121 IMS / MMD connection
122 Media control unit
123 Handover control unit
124 Authentication / Location Registration Department
131 Media converter
132 Handover processing unit
200 Femto net
300 circuit switching network
400 IMS / MMD network

Claims (12)

A femtocell system that employs an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain),
A first gateway device that exchanges call processing signals with an MSC (Mobile Switching Center) that performs handover processing of a mobile terminal under a circuit switching network, and a second gateway that connects a voice path with the MSC And a femtocell system.   The first gateway device communicates with the MSC to exchange information necessary for handover between the circuit-switched network and the femtocell network, and controls the second gateway device to control the second gateway device. The femtocell system according to claim 1, wherein a voice path between two gateway devices and the MSC is set.   The first and second gateway devices are provided at an entrance of an IMS / MMD network, and simulate a SIP (Session Initiated Protocol) terminal viewed from the IMS / MMD network. The femtocell system according to 2. The first gateway device is a Femto-GW (Femto GateWay),
The femtocell system according to any one of claims 1 to 3, wherein the second gateway device is a Femto-MGW (Femto Media Gateway). A gateway device used in a femtocell system adopting an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain),
A first means for exchanging a call processing signal with a mobile switching center (MSC) that performs a handover process for a mobile terminal under a circuit switched network, and another gateway device for connecting a voice path with the MSC. And a second means for controlling the gateway device. The first means communicates with the MSC to exchange information necessary for handover between the circuit switched network and the femtocell network;
6. The gateway device according to claim 5, wherein the second means sets the voice path between the other gateway device and the MSC by controlling the other gateway device.   The self-device and the other gateway device are provided at the entrance of the IMS / MMD network, and simulate a SIP (Session Initiated Protocol) terminal viewed from the IMS / MMD network. The gateway device described. The device itself is Femto-GW (Femto GateWay),
The gateway device according to claim 5, wherein the other gateway device is a Femto-MGW (Femto Media Gateway). A handover method between circuit-switched networks used in a femtocell system adopting an IMS / MMD connection method in which call processing is integrated into IMS (IP Multimedia Subsystem) / MMD (MultiMedia Domain),
The first gateway device exchanges call processing signals with an MSC (Mobile Switching Center) that performs handover processing of mobile terminals under the circuit switching network,
A handover method between circuit-switched networks, wherein a voice path is connected to the MSC at a second gateway device.   The first gateway device communicates with the MSC to exchange information necessary for handover between the circuit-switched network and the femtocell network, and controls the second gateway device to control the second gateway device. 10. The inter-circuit-switched network handover method according to claim 9, wherein a voice path is established between the two gateway devices and the MSC.   The first and second gateway devices are provided at an entrance of an IMS / MMD network, and simulate a SIP (Session Initiated Protocol) terminal viewed from the IMS / MMD network. The inter-circuit-switched network handover method described. The first gateway device is a Femto-GW (Femto GateWay),
12. The inter-circuit-switched network handover method according to claim 9, wherein the second gateway device is a Femto-MGW (Femto Media Gateway).

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