KR101139931B1 - Method for seamless handover between heterogenious networks - Google Patents

Abstract

The present invention relates to a seamless handover processing method between heterogeneous networks, and more particularly, seamlessly between heterogeneous networks using an IP-PBX or a private VoIP server supporting a Session Initiation Protocol (SIP) or an Internet Protocol Multimedia Subsystem (IMS) protocol. It relates to a technique for handling handover.
The present invention relates to a handover processing method for a Fixed Mobile Convergence (FMC) terminal associated with a Fixed Mobile Convergence Private Branch Exchange (FMC PBX), comprising: (a) a signal from the FMC terminal to which call channel 1 (leg 1) is connected; Determining a handover waiting state for the FMC terminal based on the strength; (b) connecting a call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined; (c) combining the call channel 1 and the call 2; (d) determining the handover state based on the signal strength from the FMC terminal; And (e) if the handover state is determined, releasing call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2).

Description

How to handle handover between heterogeneous networks {METHOD FOR SEAMLESS HANDOVER BETWEEN HETEROGENIOUS NETWORKS}

The present invention relates to a seamless handover processing method between heterogeneous networks, and more particularly, Internet Protocol-Private Branch Exchange (IP-PBX) or Private VoIP that supports Session Initiation Protocol (SIP) or Internet Protocol Multimedia Subsystem (IMS) protocol. (Voice over Internet Protocol) relates to a technology for processing seamless handover between heterogeneous networks using a server.

Currently, various wireless access services are provided worldwide, such as outdoor macro mobile communication networks such as Code Division Multiple Access (CDMA), Wideband Code Division Multiple Access (WCDMA), and Wireless Broadband (Wibro) and indoor WiFi (Wireless Fidelity). Each of these services has different advantages and disadvantages in terms of transmission speed, mobility, and charges. Therefore, heterogeneous network services provided through interworking of different network service systems are making efforts to obtain high competitiveness in terms of customer convenience and service operation of service providers through mutual supplementation, and a representative example is wired / wireless convergence service.

Wired and wireless convergence (hereinafter referred to as FMC (Fixed Mobile Convergence)) service is a service that can use a wired communication service provided through a wired network and a wireless communication service provided through a wireless network as one terminal. This FMC service is based on IP (Internet protocol), and as the standard technology of IMS (IP Multimedia Service) proposed to integrate all heterogeneous networks into IP networks and provide complete service regardless of communication network, IMS-based FMC services are actively being developed.

Meanwhile, in the 2G network generation, an initial FMC service of an unlicensed mobile alliance (UMA) method was implemented. The initial FMC service uses a mobile communication service in an outdoor macro cell, and an indoor picocell uses a mobile communication service through a WLAN access point. It was provided. The mobile call processing signal of the terminal entering the room is transparently connected to the UNC (UMA Network Controller) using a wireless LAN and a high-speed network, and thereafter, a service provider's Serving GPRS Support Node (SGSN) / GGSN (General Packet Radio Service). ) And mobile service center (MSC) to receive voice and packet services.

The dual mode terminal operating in such an environment has a disadvantage in that handover is not supported between the macrocell network and the picocell network, and the system mode must be manually selected.

High frequency of mobile phone usage and traffic distribution in indoor environment, elimination of poor wireless quality indoor environment, network deployment and design for high-speed wireless packet service in 4G (Generation) system, transition to the age of TPS / QPS service, various With the emergence of smart phones that require a wireless access method, there is an increasing demand for FMC services.

In response to these needs, 3GPP / 3GPP2 has defined UMA and femtocell standard technologies.

When IMS network technology is commercialized, WiFi-based FMC technology, 2G / 3G mobile communication, or femtocell services based on portable wireless Internet such as Wibro can be integrated into IP core network to support seamless handover between heterogeneous networks. FMC service is available.

When IMS network technology is commercialized, WiFi-based FMC technology, femtocell services based on portable wireless Internet such as 2G / 3G mobile communication or Wibro are all integrated into IP core network, enabling FMC service that can support seamless handover between heterogeneous networks.

The key important technology in FMC service is mobility management technology that can freely handover between heterogeneous networks. Technology to handle handover between two heterogeneous wireless networks to provide mobility or handover between pico or femtocell network environment such as home or office and outdoor macro cell includes VCC (Voice Call Continuity) standard specification. Any technology that can handle handovers between various networks at the data link layer is a media independent handover (MIH) standard of I EEE 802.21. This technical standard is designed so that handover processing is performed by exchange or IMS servers in the operator network.

Meanwhile, as a specific handover implementation technology in the FMC service network,

-System and method for Fixed Mobile Convergence Using a Residential Gateway Apparatus (Motorola, USA, Pub.No .: 2009/0197594 A1),

Method and Apparatus for Supporting SIP / IMS_based Femtocells (Tatara System, Pub. No .: 2009/0067417 A1),

These documents suggest a method for a handover procedure in an environment in which a related call processing server and a media gateway are disposed and processed in an operator network.

In the indoor (home, office) environment of the FMC service environment, the terminal operates both voice service and data service in packet mode (PS), whereas the outdoor terminal is used in circuit mode (CS: Circuit) depending on the type of mobile communication network. Because of operating in switching or packet mode, the heterogeneous handover becomes a form of operating in PS-CS or PS-PS mode.

In the scenario of switching from packet mode to circuit mode, voice disconnection time may be long due to problems such as system synchronization during handover of different heterogeneous networks, and femtocell in scenario of switching from indoor packet mode to outdoor packet mode. When using the same indoor and outdoor mobile communication method, a single mode modem is used, so it takes longer than 2 seconds to disconnect an existing link and allocate a DHCP IP address on a new link. There is a problem in that seamless handover is not easy due to disconnection.

The present invention has been made to solve the above-described problems, and before the actual handoff is performed in the handover area between the two links between the indoor FMC network and the outdoor network using a dual modem for connecting to the indoor network and the outdoor network The purpose is to provide a seamless handover in which an existing call channel is not disconnected when an actual handoff is performed by bonding two channels by bonding two channels while simultaneously activating two legs for a network connection.

In addition, the present invention provides a seamless handover using an IP-PBX or a private VoIP server that supports the SIP or IMS protocol, so that the network operator's switchboard or IMS server does not rely on the same call processing-related device and the indoor femto cell. Another object is to provide a seamless handover that guarantees mobility between outer macro cells.

The method for processing handover between heterogeneous networks according to an embodiment of the present invention is a handover processing method for an FMC terminal associated with an FMC PBX. Determining a handover waiting state for the FMC terminal; (b) connecting a call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined; (c) combining the call channel 1 and the call 2; (d) determining the handover state based on the signal strength from the FMC terminal; And (e) if the handover state is determined, releasing call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2).

In addition, the handover processing method between heterogeneous networks according to an embodiment of the present invention, in the handover processing method for the FMC terminal associated with the FMC PBX, when an outgoing call from the FMC terminal to the external telephone is requested in response to the request The FMC PBX connecting a call channel 1 (leg 1) with an FMC terminal; The FMC PBX calling the external telephone to connect the external telephone with call channel 0 (leg 0), wherein the FMC terminal and the external telephone are voiced through call channel 1 (leg 1) and call channel 0 (leg 0). Making a call-; Determining a handover waiting state for the FMC terminal based on the signal strength from the FMC terminal to which the call channel 1 (leg 1) is connected; Connecting call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined; Combining the call channel 1 and the call channel 2; Determining the handover state based on the signal strength from the FMC terminal; And when the handover state is determined, canceling call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2)-call channel 2 (leg 2) and call channel 0 ( leg 0) and the FMC terminal and the external telephone perform a voice call.

In addition, the method for processing handover between heterogeneous networks according to an embodiment of the present invention is a handover processing method for an FMC terminal associated with an FMC PBX, in which an incoming call is requested to an FMC terminal by an external telephone in response to the request. FMC PBX calls the FMC terminal to establish a call channel (leg 1); The FMC PBX connecting call channel 0 with leg 0 in response to a call of the external telephone-an FMC terminal and an external phone through call channel 1 and call channel 0 Makes a voice call-; Determining a handover waiting state for the FMC terminal based on the signal strength from the FMC terminal to which the call channel 1 (leg 1) is connected; Connecting call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined; Combining the call channel 1 and the call channel 2; Determining the handover state based on the signal strength from the FMC terminal; And when the handover state is determined, canceling call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2)-call channel 2 (leg 2) and call channel 0 ( via leg 0), the FMC terminal and the external telephone make a voice call; It is configured to include.

The present invention described above provides seamless handover through the installation of an IP-PBX-based FMC PBX or a private VoIP server for seamless handover between a femtocell corresponding to an indoor FMC network and an external macrocell without relying on a network operator's exchange system. There is an effect that can provide a possible FMC service.

1 is a schematic diagram of an entire network to which the present invention is applied;
2 is a main block diagram of an FMC terminal and an FMC PBX according to an embodiment of the present invention.
3 is a flowchart illustrating an outgoing call processing process of an indoor FMC terminal according to an embodiment of the present invention.
4 is a flowchart illustrating an incoming call processing process of an indoor FMC terminal according to an embodiment of the present invention.
5 is a flowchart illustrating a call processing process of an outdoor FMC terminal according to an embodiment of the present invention.
6 is a flowchart illustrating a call processing process of an outdoor FMC terminal according to an embodiment of the present invention.
7 is a main block diagram of an FMC terminal and an MGW according to this embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail.

1 is a schematic diagram of an entire network to which the present invention is applied.

The entire network includes an indoor FMC network 100, a VoIP network 200, a mobile communication network 300, other networks 400, and the Internet 500.

The indoor FMC network 100 includes an IP-based PBX 120 and an FMC terminal 110 supporting the FMC service. The FMC PBX 120 includes a wireless access point (AP) for an internal wireless LAN. ), And the external network is connected to the IP network through a network interface, for example, an xDSL interface. Of course, a separate gateway or AP, which is only responsible for various network functions such as normal AP function, external network access function, DHCP function, IP sharing function, and routing function, is installed separately, and the FMC PBX 120 configures the system to be responsible for FMC voice call function only. Although it is preferable to build in a separate type, in the present embodiment they are represented as a single system for convenience.

A wireless connection method between the indoor FMC terminal 110 and the FMC PBX 120 may configure a picocell or femtocell, and the wireless connection method may be a variety of wireless LAN (WiFi), Wibro, CDMA, WCDMA, GSM, etc. One of the wireless connection methods can be used.

The VoIP network 200 to which the FMC PBX 120 is connected through the Internet 500 performs a call session control function (CSCF) 210 that enables various multimedia services by performing SIP-based call processing control and session maintenance functions. FMG application server on which the MGW 220 performing the connection to the media channel, the MGCF 230 performing the call control related to the connection control on the media channel in the MGW 220, and the application for providing the FMC service are executed. AAA server (Authentication, Authorization, Accounting Server, 250) and user registration / change management, authentication, which is a server that includes 240 and provides a user's computer resource access processing and service authentication, authorization and charge calculation functions And a home subscriber server (HSS) 260 that manages all subscriber information for call / session control such as authorization, location, session routing, and billing. Meanwhile, the CSCF 201, the MGW 220, and the AAA server 250 of the VoIP network 200 communicate with the FMC PBX 120 of the indoor FMC network 100 through the PDIF 510.

The VoIP network 200 may provide a call path for a phone call between the FMC terminal 110 and the external phone 410 located in the indoor FMC network 100 through interworking with the other network 400. In addition, the VoIP network 200 is a telephone call between the outdoor FMC terminal 310 and the external telephone 410 located outside the indoor FMC network 100 through interworking with the mobile communication network 300 and / or the other network 400. It can provide a channel for the call.

 1, the indoor FMC terminal 110 and the outdoor FMC terminal 310 is a single FMC terminal, the FMC terminal located in the indoor FMC network 100 is denoted by the indoor FMC terminal 110, the indoor FMC network ( The FMC terminal located outside 100 is designated as the outdoor FMC terminal 310.

When the FMC terminal operates as an indoor FMC terminal 110, it is connected to the FMC PBX 120 and operates as a wireless telephone in the premises, and when operating as an outdoor FMC terminal 310, a corresponding mobile communication network to which the FMC terminal is subscribed ( 300) to operate as a normal mobile phone. The FMC terminal is equipped with a conventional dual mode wireless modem for communication between the indoor FMC network 100 and the mobile communication network 300. In addition, the FMC terminal may have three numbers corresponding to a telephone number of an external mobile telephone network, a telephone number of a private VoIP network, and an extension number of an internal network.

In an embodiment of the present invention, the FMC terminal simultaneously configures a link with the mobile communication network 300, which is an external network, in a state in which a link with the indoor LAN-based FMC network 100 is established through a dual mode wireless modem. By such a link configuration method, an embodiment of the present invention can implement diversity effects and seamless handover.

The FMC PBX 120 is an IP-based system supporting the IMS protocol or the SIP-based VoIP protocol, and operates in conjunction with the subscribed IMS core network.

The FMC PBX 120 can provide internal calls and various additional services among subscribers in the premises network using the IMS protocol, and the same IMS in conjunction with call processing, subscriber location, application server, etc. of the subscribed individual IMS service system It can provide call service between subscribers in service network. In addition, the FMC PBX 120 interworks with the MGW 220 and the application server installed in the VoIP network 200 to provide call services with telephone terminals accommodated in various external networks such as existing telecommunication networks, PSTN networks, and other VoIP networks. to provide.

By using the telephone adapter (TA) function that connects the internal and external networks in the PBX device, the CSCF server function and the media gateway function to handle call processing, various communication services that utilize the FMC PBX as an anchor system are provided. It is possible.

In the present invention, the "handover" refers to an FMC terminal operating indoors as an indoor FMC terminal 110 and then moved to a position outside the indoor FMC network 100 to operate as an outdoor FMC terminal 310 or an outdoor FMC terminal ( It is generated when operating as the indoor FMC terminal 110 is moved to a location in the indoor FMC network 100, 310.

In one embodiment of the present invention, using the FMC PBX 120 as an anchor system to perform a handover to the FMC terminal.

FIG. 2 is a block diagram of the FMC terminal and the FMC PBX 120 according to an embodiment of the present invention. As shown in FIG. 2, the FMC terminal is an indoor wireless modem for communication with the FMC PBX 120. 111, a voice call processing unit 112 for performing data processing for the transmission voice and the reception voice for a telephone call, and an outdoor wireless modem 311 for communication with the mobile communication network 300.

The voice call processor 112 processes a voice call and a communication protocol, and simultaneously activates two network cards, that is, an indoor wireless modem 111 and an outdoor wireless modem 311, and uses both IP addresses for both paths. Sends and receives packets. Packets transmitted on two channels at the same time are combined in an appropriate manner through the FMC terminal and the FMC PBX 120, and the method of combining the channels may use known techniques. Synchronization of two inter-channel packets can be implemented using the packet number attached to the VoIP packet.

However, if the link 3 and the link 4 with the mobile communication network form a line mode other than the packet mode, the channel combining method may be slightly complicated. One of the methods is to convert the digital voice packet of the VoIP network 200 into the digital voice and packet of the indoor channel. Or a hard handover after converting voice packets of the VoIP network 200 to analog.

The FMC terminal is equipped with a plurality of applications for playing voice calls and various media, and is provided with means for inputting various control commands and operation control commands of the application and control means for operating the corresponding application according to the input commands. For convenience of description, in FIG. 2, only the functional elements corresponding to the exemplary embodiment of the present invention are illustrated without the description of the functional elements for performing the ordinary functions. The same applies to the FMC PBX 120.

On the other hand, the FMC PBX 120 according to an embodiment of the present invention is a network card 1 121 for communicating with the mobile communication network 300, a network card 2 (123) for communicating with the indoor FMC terminal 110, and The voice call processor 122 performs a series of processes related to the voice call performed by the premises exchange.

In FIG. 2, link 1 indicates a link configured between the FMC terminal and the FMC PBX 120, link 3 indicates a link configured between the FMC terminal and the mobile communication network, and link 4 configures between the FMC PBX 120 and the mobile communication network. Represents a link.

The FMC terminal has a call channel 1 (leg 1) connected through a link 1 connected to the FMC PBX 120 in the activated state of the indoor wireless modem 111, and a call channel 0 (leg) directly connected to an external telephone 410. 0) can be used to make a phone call with the external telephone (410).

In this state, when the FMC terminal moves to the outdoors, the link 4 configured with the FMC PBX 120 and the mobile communication network 300 is configured by the FMC PBX 120 calling the FMC device through the mobile communication network 300. As the communication network 300 calls the FMC terminal, link 3 is configured between the mobile communication network 300 and the FMC terminal so that call channel 2 (leg 2) is connected. As a result, seamless handover can be performed through the call channel 1 and the call channel 2.

3 to 6, the call processing process between the indoor FMC terminal 110 or the outdoor FMC terminal 310 and the external telephone 410 will be described.

First, a call processing process for the indoor FMC terminal 110 in an embodiment of the present invention will be described.

3 is a flowchart illustrating an outgoing call processing procedure from the indoor FMC terminal 110 according to an embodiment of the present invention.

When a call request for connection with the external telephone 410 is generated from the indoor FMC terminal 110, which is assigned the premises number (S4), the FMC PBX 120 connects the call with the indoor FMC terminal 110 to the indoor FMC terminal. Call channel 1 (leg 1) between the 110 and the FMC PBX 120 is connected (S6).

At the same time, the FMC PBX 120 calls the external telephone 410 via the call request, and the call channel 0 (leg) between the FMC PBX 120 and the external telephone 410 by the external telephone 410 responding to the call request. 0) is connected (S8).

In one embodiment of the present invention, the FMC PBX 120 is provided with a TA function or an MGW function and a call processing function interworking with an external network to operate as an anchor system, and the FMC PBX 120 directly by the corresponding function at step S8. Outgoing call processing is performed with the external telephone 410, and the FMC PBX 120 configures call channel 0 (Leg 0) with the external telephone 410 in the direct line mode. In this case, the FMC PBX 120 configures call channel 0 (Leg 0) with the external telephone 410 in the direct line mode.

In another embodiment of the present invention, the MGW function and the call processing function are not provided in the FMC PBX 120, and the CSCF 210 of the VoIP network 200 (see FIG. 1) may operate as an anchor system. In step S8 it may be implemented by connecting to the external telephone 410 via the VoIP network 200. According to this method, after the FMC PBX 120 requests a call from the CSCF 210 (see FIG. 1) of the VoIP network 200, the call signal processing with the external telephone 410 is performed through the CSCF 210. The call channel 0 (Leg 0) is connected through the MGW 220 (see FIG. 1) of the VoIP network 200. In this case, the packet mode section is between the FMC PBX 120 and the MGW 220, and the line mode section is between the MGW 220 and the external telephone 410.

In the description of the present invention, for convenience of explanation, the external telephone 410 and the FMC PBX 120 or the CSCF 210 has been described to be directly connected, but those skilled in the art actually the external network 400 accommodated with the external telephone 410 It will be appreciated that it communicates with the external telephone 410 via an exchange facility (eg, TDX exchange, MSC, etc.) provided in the. Accordingly, the description that the external telephone 410 is directly connected to the FMC PBX 120 or the CSCF 210 may be understood as a call processing procedure through the exchange facility of the external network 400.

As the call channel 1 (leg 1) and the call channel 0 (leg 0) are connected, the indoor FMC terminal 110 performs a phone call with the external telephone 410 through the FMC PBX (120) (S10).

In this state, the FMC PBX 120 determines the handover standby state to the indoor FMC terminal 110 from the signal strength of the indoor FMC terminal 110 (S12), the indoor FMC terminal 110 is gradually moved to the outdoor If the signal strength is lower than the first threshold, it is determined that the handover wait (Yes in S12). Here, the "handover wait state" refers to a state for preparing for a "handover state" to the mobile communication network 300, which is not a time when a handover is actually performed, but may occur later. It is preferable to set the value to a level higher than the second threshold for signal strength for determining the handover.

If it is determined in step S12 that the handover waiting state is not determined (No in S12), the FMC PBX 120 proceeds to step S10, while in the result of the determination of step S12, the handover waiting state is determined (Yes in S12). The FMC PBX 120 calls the indoor FMC terminal 110 through the mobile communication network 300 by dialing the telephone number of the mobile communication network 300 assigned to the indoor FMC terminal 110. In response to the call, as the outdoor wireless modem 311 of the indoor FMC terminal 110 is activated, call channel 2 (leg 2) between the indoor FMC terminal 110 and the FMC PBX 120 is connected (S14). Accordingly, the indoor FMC terminal 110 is in a state in which the indoor wireless modem 111 and the outdoor wireless modem 311 are simultaneously activated, and the indoor FMC network 100 is connected between the indoor FMC terminal 110 and the FMC PBX 120. The call channel 1 (leg 1) through and the call channel 2 (leg 2) through the mobile communication network 300 is connected.

In this state, the FMC PBX 120 detects a handover state based on the signal strength from the indoor FMC terminal 110 (S16). If the signal strength from the indoor FMC terminal 110 is lower than or equal to the second threshold in step S16, the FMC PBX 120 determines to be in the handover state (Yes in S16) and enters step S18. On the other hand, if the signal strength from the indoor FMC terminal 110 is greater than the second threshold, the FMC PBX 120 proceeds to step S14 while maintaining the handover standby state. Here, the second threshold is a value different from the above-described first threshold, and is a value for determining the signal strength to actually proceed with the hand of.

In step S18, the indoor FMC terminal 110 transmits and receives data in duplicate through call channel 1 (leg 1) and call channel 2 (1eg 2), while call channel 1 (leg 1) and call channel 2 (leg 2). After bonding (B1) to combine the packets received at the same time through the call channel 1 (leg 1) and the call channel 2 (leg 2) (S18), the call channel 1 according to the handover completion instruction of the FMC PBX (120) Release (leg 1) (S20). As a result, the outdoor FMC terminal 310 communicates with the external telephone 410 while being connected to the FMC PBX 120 through the call channel 2.

In an embodiment of the present invention, when the outdoor FMC terminal 310 transmits and receives data in duplicate through the call channel 1 and the call channel 2, the call channel 2 and the call channel 2, respectively. When (leg 2) operates in packet mode, both dual channels can make calls using VoIP, so packets received through both paths can be combined and used using appropriate channel bonding techniques. As a result, when combined with the diversity mechanism, the call quality can be improved and the handover can be handled seamlessly. If the call channel 2 (leg 2) operates in the circuit mode, the outdoor FMC terminal 310 must perform a hard handover process.

In step S20, as the call channel 1 (leg 1) between the outdoor FMC terminal 310 and the FMC PBX 120 is released, the outdoor FMC terminal 310 and the FMC PBX 120 are connected through the call channel 2 (leg 2). The entire handover process is completed by transmitting and receiving information.

In the exemplary embodiment of the present invention, the FMC PBX 120 operates as an anchor system, thereby describing a process in which the handover procedure corresponding to steps S16 to S20 is performed by the FMC PBX 120.

In another embodiment of the present invention, the CSCF 210 of the VoIP network 200 operates as an anchor system so that a handover procedure corresponding to steps S18 to S20 is performed through interworking between the FMC PBX 120 and the CSCF 210. Can be performed. That is, in another embodiment, when the FMC PBX 120 requests a handover to the CSCF 210, the CSCF 210 requests a call connection to the outdoor FMC terminal 310 to call channel 2 (through the MGW 220). After the leg 2) is connected, when the CSCF 210 notifies the FMC PBX 120 of the handover completion, the FMC PBX 120 releases call channel 1 (leg 1) with the indoor FMC terminal 110. Thus, the outdoor FMC terminal 310 may be connected to the external telephone 410 through the call channel (leg 0) in the state connected to the MGW 220 through the call channel (leg 2).

Next, an incoming call processing procedure to the indoor FMC terminal 110 according to an embodiment of the present invention will be described with reference to the flowchart shown in FIG. 4.

When the external telephone 410 makes a call using the extension number of the FMC terminal, the call request from the external telephone 410 is transmitted to the FMC PBX 120 through the CSCF 210 of the VoIP network 200 (S32). ).

The FMC PBX 120 makes a call request to the indoor FMC terminal 110, connects the indoor FMC terminal 110 to the call channel 1 (leg 1) (S34), and responds to a call request from the external telephone 410. The external telephone 410 and the call channel 0 (leg 0) are connected (S36).

When the call request from the FMC PBX 120 is received, the CSCF 210 connects a call channel 0 between the FMC PBX 120 and the external telephone 410 through the MGW 220, thereby connecting the FMC PBX ( A telephone call between the indoor FMC terminal 110 and the external telephone 410 is performed through the 120.

Thereafter, the FMC PBX 120 proceeds to step S12 of FIG. 3 and performs the seamless handover procedure for the indoor FMC terminal 110 by performing the above steps S12 to S20.

As described above, in one embodiment of the present invention, because the FMC PBX 120 operates as an anchor system, the FMC PBX 120 performs a seamless handover procedure for the indoor FMC terminal 110, but the present invention When the CSCF 210 of the VoIP network 200, which is another embodiment of the present invention, operates as an anchor system, a handover procedure for the indoor FMC terminal 110 is performed through the interworking of the FMC PBX 120 and the CSCF 210. Can be.

Even if the indoor FMC terminal 110 moves to the outdoor FMC terminal 310 through the above-described process, the outdoor FMC terminal 310 and the external telephone 410 can stably perform a voice call.

Next, a call processing process for the outdoor FMC terminal 310 will be described in an embodiment of the present invention.

5 is a flowchart for explaining an outgoing call processing procedure from an outdoor FMC terminal 110 according to an embodiment of the present invention.

When the user of the outdoor FMC terminal 310 dials the telephone number of the external telephone 410, the outdoor FMC terminal 310 requests the mobile communication network 300 to call the representative number of the FMC PBX 120 as the called number. While transmitting, the called party information of the external telephone 410 is also transmitted (S50). At this time, the outdoor FMC terminal 310 communicates with the mobile communication network 300 by using the telephone number assigned from the mobile communication network 300, and the call request is the FMC via the mobile communication network 300 and the VoIP network 200. Delivered to PBX 120.

The FMC PBX 120 calls the external telephone 410 through a call request, and the call channel 0 (leg 0) between the FMC PBX 120 and the external telephone 410 is connected by the external telephone 410 answering the call. It becomes (S52). The call processing procedure between the FMC PBX 120 and the external telephone 410 is performed via the CSCF 210 of the VoIP network 200, and the CSCF 210 is connected to the call channel 0 through the MGW 220. This is because the outgoing call was delivered to the FMC PBX 120 via the VoIP network 200.

Subsequently, the FMC PBX 120 responds to the call request from the outdoor FMC terminal 310 to the VoIP network 200, whereby call channel 1 (leg 1) between the FMC PBX 120 and the outdoor FMC terminal 310 is connected. (S54). This call channel leg 1 is connected via the mobile communication network 300.

As the call channel 1 (leg 1) and the call channel 0 (leg 0) are connected, the outdoor FMC terminal 310 can perform a phone call with the external telephone 410 through the FMC PBX 120 (S56). ).

In this state, the FMC PBX 120 monitors the entry of the indoor FMC network 100 of the outdoor FMC terminal 310 through the detection of the signal strength of the outdoor FMC terminal 310, and thus the hand for the outdoor FMC terminal 310. The over wait state is determined (S58).

When the outdoor FMC terminal 310 enters the indoor FMC network 100 and the signal strength is higher than or equal to the third threshold value, the outdoor FMC terminal 310 determines to wait for handover (Yes in S58). Here, the "handover wait state" means a state for preparing a "handover state" to the indoor FMC network 100, which may occur later, although the handover is not actually performed. It is desirable to set a value lower than a fourth threshold for signal strength for determining normal handover.

If it is determined in step S58 that the handover waiting state is not determined (No in S58), the FMC PBX 120 proceeds to step S56, while if the determination result of step S58 is determined, the handover waiting state is determined (Yes in S58). The FMC PBX 120 calls the indoor FMC terminal 110 through the indoor FMC network 100 by dialing an extension number assigned to the outdoor FMC terminal 310. The indoor FMC terminal 110 is the same terminal as the outdoor FMC terminal 310. As the location is moved from the outdoor to the indoor, the communication method is changed from the outdoor FMC terminal 310 to the indoor FMC terminal 110.

In response to the call, as the indoor wireless modem 111 of the indoor FMC terminal 110 is activated, the call channel 2 (leg 2) between the indoor FMC terminal 110 and the FMC PBX 120 is connected (S60). . At this time, the indoor FMC terminal 110 is connected to the call channel 1 (leg 1) through the indoor wireless modem 111, the call channel 0 (leg 0) is connected through the outdoor wireless modem 311. The indoor wireless modem 111 is in a state in which the outdoor wireless modem 311 is simultaneously activated.

In this state, the FMC PBX 120 detects a handover state based on the signal strength from the indoor FMC terminal 110 (S62). If the signal strength from the indoor FMC terminal 110 is higher than or equal to the fourth threshold in step S62, the FMC PBX 120 determines to be in a handover state (Yes in S62) and enters step S64. On the other hand, if the signal strength from the indoor FMC terminal 110 is less than the fourth threshold, the FMC PBX 120 proceeds to step S60 while maintaining the handover standby state. Here, the fourth threshold is a value different from the above-described third threshold, and is a value for determining the signal strength to actually proceed with the hand of.

In step S64, the indoor FMC terminal 110 transmits and receives data in duplicate through call channel 1 (leg 1) and call channel 2 (1eg 2), while call channel 1 (leg 1) and call channel 2 (leg 2). After bonding (B1) to combine the packets received at the same time through the call channel 1 (leg 1) and the call channel 2 (leg 2) (S64), the call channel 1 according to the handover completion instructions of the FMC PBX (120) Release (leg 1) (S66). As a result, the outdoor FMC terminal 310 communicates with the external telephone 410 while being connected to the FMC PBX 120 through the call channel 2.

In an embodiment of the present invention, when the outdoor FMC terminal 310 transmits and receives data in duplicate through the call channel 1 and the call channel 2, the call channel 2 and the call channel 2, respectively. When (leg 2) operates in packet mode, both dual channels can make calls using VoIP, so packets received through both paths can be combined and used using appropriate channel bonding techniques. As a result, when combined with the diversity mechanism, the call quality can be improved and the handover can be handled seamlessly. If the call channel 2 (leg 2) operates in the circuit mode, the outdoor FMC terminal 310 must perform a hard handover process.

In step S66, as the call channel 1 (leg 1) between the outdoor FMC terminal 310 and the FMC PBX 120 is released, the outdoor FMC terminal 310 and the FMC PBX 120 are connected through the call channel 2 (leg 2). The entire handover process is completed by transmitting and receiving information.

In the exemplary embodiment of the present invention, the FMC PBX 120 operates as an anchor system, thereby describing a process in which the handover procedure corresponding to steps S58 to S66 is performed by the FMC PBX 120.

However, in another embodiment of the present invention, since the CSCF 210 of the VoIP network 200 operates as an anchor system, the handover procedure corresponding to steps S58 to S66 is linked to the FMC PBX 120 and the CSCF 210. It can be performed through. That is, in another embodiment, when the FMC PBX 120 requests a handover to the CSCF 210, the CSCF 210 requests a call connection to the indoor FMC terminal 110 and calls the call channel 2 through the MGW 220. After the leg 2) is connected, when the CSCF 210 notifies the FMC PBX 120 of the handover completion, the FMC PBX 120 releases call channel 1 (leg 1) with the outdoor FMC terminal 310. Thus, the indoor FMC terminal 310 may be connected to the external telephone 410 through the call channel (leg 0) in the state connected to the MGW 220 through the call channel (leg 2).

Referring to the flowchart shown in Figure 6 will be described the incoming call processing to the outdoor FMC terminal 110 according to an embodiment of the present invention.

When the external telephone 410 makes a call using the extension number of the FMC terminal, the call request from the external telephone 410 is transmitted to the FMC PBX 120 through the CSCF 210 of the VoIP network 200 (S80). ).

The FMC PBX 120 responds to a call request from the external telephone 410 through a call channel through the mobile communication network 300 with the external telephone 410 through the CSCF 210 and the MGW 220 of the VoIP network 200. Connect 0 (leg 0) (S82).

At the same time, the FMC PBX 120 connects the outdoor FMC terminal 310 and the call channel 1 (leg 1) through the mobile communication network 300 (S84).

Thus, a telephone call between the outdoor FMC terminal 310 and the external telephone 410 through the call channel 0 (leg 0) connected through the VoIP network 200 and the call channel 1 (leg 1) connected through the mobile communication network 300. Is performed (S86).

Thereafter, the FMC PBX 120 proceeds to step S58 of FIG. 5 and performs the above-described steps S58 to S66 to perform a seamless handover procedure for the outdoor FMC terminal 310.

As described above, in one embodiment of the present invention, because the FMC PBX 120 operates as an anchor system, the FMC PBX 120 performs a seamless handover procedure for the outdoor FMC terminal 310, but the present invention When the CSCF 210 of the VoIP network 200, which is another embodiment of the present invention, operates as an anchor system, a handover procedure for the outdoor FMC terminal 110 is performed through the interworking of the FMC PBX 120 and the CSCF 210. Can be.

Even if the outdoor FMC terminal 310 moves to the indoor FMC terminal 110 through the above-described process, the indoor FMC terminal 110 and the external telephone 410 can stably perform a voice call.

7 is a main block diagram of the FMC terminal and the FMC PBX 120 according to this embodiment of the present invention, and the same reference numerals and names are given to components that perform functions similar to those shown in FIG. The detailed description thereof is omitted.

As described above, this embodiment of the present invention is an embodiment of the case where the CSCF 210 of the VoIP network 200 operates as an anchor system, and the FMC terminal is an FMC in the activated state of the indoor wireless modem 111. Call channel 1 (leg 1) connected through link 1A to PBX 120A and link 2 connected between network card 2 223 of FMC PBX 120A and MGW 220 A telephone call may be performed with the external telephone 410 using leg 0.

 In this state, when the FMC terminal moves outdoors, the outdoor wireless modem 311 of the FMC terminal is activated to configure the link 3 to the mobile communication network 300, the mobile communication network 300 is the MGW ( Link 4 is configured to connect to the call channel 2 (leg 2). At the same time, packets transmitted to call channel 1 and 2 are combined in an appropriate manner through the FMC terminal and the MGW 220, and a method of combining the channels may be performed using known techniques. Can be.

The present invention described above is not limited to the embodiments presented through the present specification, and various modifications may be made without departing from the technical spirit and aspects of the present invention.

100: indoor FMC network 200: VoIP (Voice over IP) network
300: mobile communication network 400: other network
110: indoor FMC terminal 111: indoor wireless modem
112: voice call processing unit
120: Fixed Mobile Convergence Private Branch Exchange (FMC PBX)
121, 221: network card 1 122, 222: voice call processing unit
123, 223: network card 2 310: outdoor FMC terminal
210: Call Session Control Function (CSCF)
220: MGW (Media Gateway) 311: outdoor wireless modem

Claims (7)

In the handover processing method for a Fixed Mobile Convergence (FMC) terminal associated with a Fixed Mobile Convergence Private Branch Exchange (FMC PBX),
(a) determining a handover waiting state for the FMC terminal based on a signal strength from the FMC terminal to which call channel 1 (leg 1) is connected;
(b) connecting a call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined;
(c) combining the call channel 1 and the call 2;
(d) determining the handover state based on the signal strength from the FMC terminal; And
(e) if the handover state is determined, releasing call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2).
How to handle handover between heterogeneous networks. The method according to claim 1, wherein in step (c)
The call channel 1 (leg 1) and the call channel 2 (leg 2) is in a packet mode,
Bonding both channels by bonding the call channel 1 and the call channel 2, respectively.
How to handle handover between heterogeneous networks. The method of claim 1, wherein in step (a)
The signal strength from the FMC terminal is compared with a first threshold value, which is a reference value for determining the handover waiting state, and is determined as the handover waiting state.
Handover processing method for FMC terminal. The method according to claim 1, wherein (d)
The signal strength from the FMC terminal is compared with a second threshold, which is a reference value for determining the handover state, and is determined as the handover state.
How to handle handover between heterogeneous networks. The method according to claim 3 or 4,
The first threshold is greater than the second threshold
How to handle handover between heterogeneous networks. In the handover processing method for a Fixed Mobile Convergence (FMC) terminal associated with a Fixed Mobile Convergence Private Branch Exchange (FMC PBX),
When the outgoing call from the FMC terminal to the external telephone is requested, the FMC PBX connecting a call channel 1 (leg 1) with the FMC terminal in response to the request;
The FMC PBX calling the external telephone to connect the external telephone with call channel 0 (leg 0), wherein the FMC terminal and the external telephone are voiced through call channel 1 (leg 1) and call channel 0 (leg 0). Making a call-;
Determining a handover waiting state for the FMC terminal based on the signal strength from the FMC terminal to which the call channel 1 (leg 1) is connected;
Connecting call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined;
Combining the call channel 1 and the call channel 2;
Determining the handover state based on the signal strength from the FMC terminal; And
If the handover state is determined, terminate call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2)-call channel 2 (leg 2) and call channel 0 (leg); 0) the FMC terminal and the external telephone make a voice call; Characterized in that configured to include
How to handle handover between heterogeneous networks. In the handover processing method for a Fixed Mobile Convergence (FMC) terminal associated with a Fixed Mobile Convergence Private Branch Exchange (FMC PBX),
When the incoming call is requested to the FMC terminal by an external telephone, in response to the request, the FMC PBX calls the FMC terminal to establish a call channel 1 (leg 1);
The FMC PBX connecting call channel 0 with leg 0 in response to a call of the external telephone-an FMC terminal and an external phone through call channel 1 and call channel 0 Makes a voice call-;
Determining a handover waiting state for the FMC terminal based on the signal strength from the FMC terminal to which the call channel 1 (leg 1) is connected;
Connecting call channel 2 (leg 2) to the FMC terminal when the handover waiting state is determined;
Combining the call channel 1 and the call channel 2;
Determining the handover state based on the signal strength from the FMC terminal; And
If the handover state is determined, terminate call channel 1 (leg 1) of the FMC terminal to complete the handover to call channel 2 (leg 2)-call channel 2 (leg 2) and call channel 0 (leg); 0) the FMC terminal and the external telephone make a voice call; Characterized in that it comprises
How to handle handover between heterogeneous networks.

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