MIXED MOBILE COMMUNICATION SYSTEM OF ASYNCHRONOUS
COMMUNICATION NETWORK AND SYNCHRONOUS COMMUNIC ATION NETWORK
HAVING HANDOVER FUNCTION OF MOBILE COMMUNICATION TERMINAL, AND
HANDOVER METHOD IN THE SAME
Technical Field
The present invention relates, in general, to a handover method in a mobile communication network and, more particularly, to a mobile communication system in which asynchronous and synchronous networks, between which the handover of a communication terminal can be performed, coexist, and a handover method using an Interworking Interoperability Function, which is used to exchange signals between asynchronous and synchronous MSCs in the mobile communication system.
Background Art
With the development of mobile communication technology, mobile communication networks are evolving generation by generation. Currently, a mobile communication network has a form in which a synchronous mobile communication system (CDMA mobile communication system), called a 2nd or 2.5th generation network, and an asynchronous mobile communication system (WCDMA mobile communication system), called a 3rd generation network, coexist
With the development of such mobile communication network technology, a mobile communication terminal (Dual Band Dual Mode Terminal; DBDM mobile communication terminal), capable of being used both in a synchronous type system and in an asynchronous type system, is being developed. Using such a mobile communication terminal, different types of
services can be used in the respective areas of an asynchronous type system and a synchronous type system. Such a DBDM mobile communication terminal includes an antenna, a synchronous modem unit for performing synchronous mobile communication, an asynchronous modem unit for performing asynchronous mobile communication, and a common module. Meanwhile, since the asynchronous mobile communication system is at an early stage of service and cannot provide service over a wide area due to the massive investment cost for the implementation of the system, the asynchronous mobile communication system is implemented to overlap the area of a synchronous mobile communication system. As a result, the service area of the asynchronous mobile communication system is limited, so there is a problem in that a call is disconnected in the case where subscribers to the asynchronous mobile communication system move to a synchronous area, in which an asynchronous mobile communication service is not provided, while using a service in an asynchronous area
As described above, in the case where an asynchronous mobile communication system and a synchronous mobile communication system coexist and the area of the asynchronous mobile communication system is smaller than that of the synchronous mobile communication system, handover is required to provide continuous service between the asynchronous and synchronous mobile communication systems. Furthermore, such handover needs to be supported during the use of the voice communication service of a mobile communication terminal or a reception alerting state, or while waiting for the response of a called party after the origination of a call.
Disclosure of the Invention
The present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a handover method that can provide continuous service without the disconnection of a call using an Interworking Interconnection
Function between asynchronous and synchronous MSCs as a mobile communication terminal moves from the area of an asynchronous mobile communication system to the area of a synchronous mobile communication system.
Another object of the present invention is to provide a handover method that, when a radio network controller requests handover from an asynchronous MSC, the asynchronous MSC determines whether the requested handover is handover within an asynchronous mobile communication system or handover to a synchronous mobile communication system and performs a handover process appropriate for the handover target, as a mobile communication terminal located in the area of the asynchronous mobile communication system moves to the area of the synchronous mobile communication system.
Still another object of the present invention is to provide a handover method that enables handover to the area of a synchronous mobile communication system while a mobile communication terminal uses service in the area of an asynchronous mobile communication system, is in a reception alerting state, or is in a state of wailing for a response from a called party after the origination of a call.
Brief Description of the Drawings
FIG. 1 is a diagram illustrating the construction of a mobile communication network to which the present invention is applied; FIGS. 2 and 3 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to an embodiment of the present invention;
FIGS. 4 and 5 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to another embodiment of the present invention;
FIGS. 6 and 7 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to still another embodiment of the present invention; and
FIGS. 8 to 20 are diagrams illustrating parameters included in messages necessary for the handover methods of the present invention.
Best Mode for Carrying Out the Invention
In order to achieve the above-described objects, the present invention provides a mobile communication system in which an asynchronous mobile communication system, including a node B, a radio network controller and an asynchronous Mobile Switching Center (MSC), and a synchronous mobile communication system, including a Base Transceiver Station (BTS), a Base Station Controller (BSC) and a synchronous MSC, coexist, the mobile communication system enabling handover of a Dual Band Dual Mode (DBDM) mobile communication terminal, capable of communicating with the asynchronous and synchronous systems, during voice communication, or reception alerting, or while waiting for a response after origination of a call, wherein the asynchronous and synchronous MSCs are connected to each other via an Interworking Interoperability Function (HF), and are connected to a Dual stack Home Location Register (D-HLR); the D-HLR stores and manages asynchronous subscription and synchronous subscription information of the mobile communication terminal; and the HF stores and manages the synchronous mobile communication system information, receives the synchronous subscription information of the mobile communication terminal from the D-HLR at a request of the asynchronous MSC for handover, transmits the synchronous system information and the synchronous subscription information of the mobile communication terminal to the synchronous MSC and receives a response from the synchronous MSC, thereby setting up a relay line between the asynchronous MSC and the
synchronous MSC, and requests the asynchronous MSC to release a wireless connection when the mobile communication terminal and the synchronous mobile communication system are connected to each other and notification of completion of the handover is provided by the synchronous MSC.
Preferred embodiments of the present invention are described in more detail with reference to the accompanying drawings below.
FIG. 1 is a diagram illustrating the construction of a mobile communication network to which the present invention is applied.
A mobile communication terminal 10 to which the present invention is applied is a Dual Band Dual Mode (hereinafter referred to as a 'DBDM mobile communication terminal'), and has a structure capable of providing both asynchronous mobile communication service and synchronous mobile communication service. The mobile communication terminal 10 includes a synchronous modem unit, which is a module for synchronous mobile communication, an asynchronous modem unit, which is a module for asynchronous mobile communication, and a common module, so that it wirelessly connects to each of an asynchronous mobile communication system 20 and a synchronous mobile communication system 30 and can use voice and data services.
An asynchronous mobile communication system 20 includes a node B/RNC 210 configured to include a node B, that is, a base station for performing radio section communication with the mobile communication terminal 10 and a Radio Network Controller (RNC) for controlling the node B, an asynchronous Mobile Switching Center (MSC) 220 connected to the RNC 210 and configured to perform call exchange to provide service to the mobile communication terminal 10, a Serving General Packet Radio Service (GPRS) Support Node (SGSN) 230 connected between the RNC and a GPRS network 240 and configured to maintain the location track of the mobile communication terminal 10 and perform access control and a security function, and a Gateway GPRS Support Node (GGSN) 250 connected to the SGSN 230 via the GPRS network 240, and connected to an Internet Protocol QP) network 70 to support interworking with external packets.
Furthermore, a synchronous mobile communication system 30 includes a Base Transceiver Station (BTS)/Base Station Controller (BSC) 310 configured to include a BTS for supporting radio section communication with the mobile communication terminal 10 and a BSC for controUing the BTS, an MSC 320 connected to one or more BSCs and configured to support call exchange, a Packet Data Service Node (PDSN) 330 connected to the BSC and configured to provide packet data service to subscribers, and a Data Core Network 340 configured to support the connection between the PDSN 330 and the IP network 70.
Furthermore, the MSCs 220 and 320 of the asynchronous mobile communication system 20 and synchronous mobile communication system 30 are interconnected via an Interworking Interoperability Function (DF) 60, and the HF 60 converts an asynchronous message, which is transmitted from the asynchronous MSC 220, into a synchronous message, transmits the synchronous message to the synchronous MSC 320, and stores and manages information about the synchronous mobile communication system in a database.
The asynchronous MSC 220 and the synchronous MSC 320 are connected to a No.7 common signal network 40, and connect to a Dual stack Home Location Register (D-HLR) 50 via the No. 7 common signal network 40. The D-HLR 50 stores and manages information about the subscription of the DBDM mobile communication terminal 10 to the asynchronous mobile communication system and information about the corresponding subscription to the synchronous mobile communication system, so that the asynchronous and synchronous MSCs 220 and 320 can refer to the information when performing service, such as handover.
In the above-described network configuration, the mobile communication terminal 10 located in the area of the asynchronous mobile communication system 20 periodically measures the strength of a signal from the node B, and reports the measured strength to the node B. When the strength of the signal from the node B decreases to or below a preset threshold value, the node B reports the occurrence of a handover event to the asynchronous MSC 220 via the RNC. In this case,
the node B/RNC 210 transmits neighborhood cell information and a BTS ID detected by the mobile communication terminal 10, along with the information about the occurrence of the handover event, to the asynchronous MSC 220. At this time, the mobile communication terminal 10 may be in the state of using a voice communication service, in a reception alerting state, or in the state of waiting for a response from a receiving side after the origination of a call.
When the asynchronous MSC 220 receives a handover request message from the RNC, it determines whether the requested handover is handover between neighborhood cells of the asynchronous mobile communication system 20 or handover to the synchronous mobile communication system 30 with reference to the information about adjacent cells and BTS IDs, which are received from the RNC.
In the case of handover between cells of the asynchronous mobile communication system 20, the asynchronous MSC 220 performs handover to a neighborhood cell, while in the case of handover to the synchronous mobile communication system 30, it performs handover to the synchronous MSC 320 via the HF 60. For this purpose, the HF 60 converts an asynchronous message into a synchronous message and transmits it to the synchronous MSC 320, and it must store and manage information about the synchronous mobile communication system in a database. This database includes MSC information, signaling points, and dedicated channel-related relay line information. The HF 60 selects a handover target MSC 320 based on the request of the asynchronous MSC 220 for handover and the information about the synchronous mobile communication system, creates a billing ID including the ID of the handover target MSC, and then uses the billing ID in later handover processes.
The handover process in the mobile communication system is described for the cases in which the mobile communication terminal is in the state of using a voice communication service, in a reception alerting state, or in the state of waiting for a response from a receiving side after the origination of a call.
FIGS. 2 and 3 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to an embodiment of the present invention. The diagrams illustrate a handover method in the case where a mobile communication terminal moves to the area of a synchronous mobile communication system while using voice communication service in the area of an asynchronous mobile communication system.
Referring to FIG. 2, the mobile communication terminal 10 that uses voice communication service in the area A of the asynchronous mobile communication system 20 periodically measures the strength of a signal from the currently connected node B or the strength of a signal from an adjacent BTS or node B, and reports the measured strength to the node B. As the mobile communication terminal 10 moves to an area C overlapping the area B of the synchronous mobile communication system 30, the node B requests handover from the asynchronous MSC 220 via the RNC if the strength of the signal measured by the mobile communication terminal 10 is equal to or lower than a predetermined value.
Accordingly, a process of handover of the mobile communication terminal 10 between the asynchronous mobile communication system 20 and the synchronous mobile communication system 30 is initiated via the HF 60. When the handover is completed and the asynchronous MSC 220 and the synchronous MSC 320 connect to each other via the DF 60, the mobile communication terminal 10 continuously uses the voice communication service via the BTS/BSC 310 of the synchronous mobile communication system 30. For the above-described handover during the use of the voice communication service, the mobile communication terminal 10 periodically measures the strength of a signal from the node B and reports the measured strength to the node B. When the strength of the signal from the node B decreases to or below the preset threshold value, the node B reports the occurrence of a handover event to the asynchronous MSC 220 via the RNC. In this case, the node B/RNC 210 transmits neighborhood cell information and a BTS ID detected by the mobile communication terminal 10,
along with the information about the occurrence of the handover event, to the asynchronous MSC 220.
The process of handover during the use of the voice communication service is described in more detail with reference to FIG. 3 below. As the mobile communication terminal 10 that is using the voice communication service in the area of the asynchronous mobile communication system 20 moves to the area of the synchronous mobile communication system 30, the mobile communication terminal 10 detects a signal from the synchronous mobile communication system 30, periodically measures the strength of a signal from the node B of the asynchronous mobile communication system 20 or the strength of a signal from an adjacent BTS or node B, and reports the measured strength to the node B. Accordingly, if the node B currently connected to the mobile communication terminal 10 determines that the strength of the signal between the mobile communication terminal and the node B is equal to or lower than a predetermined value, the node B requests handover from the asynchronous MSC 220 via the RNC (using IU Reloc Required) at step SlOl. The handover request message (TU Reloc Required) includes a handover-related message used in the synchronous mobile communication system. The RNC transmits the adjacent BTS information (BTS ID) and the adjacent cell information received from the mobile communication terminal 10, and the asynchronous MSC 220 determines whether the requested handover is handover between adjacent cells of the asynchronous mobile communication system or handover to the synchronous mobile communication system 30 based on the information. The handover request message (IU Reloc Required) transmitted by the RNC to the asynchronous MSC 220, as illustrated in FIG. 8, includes parameters such as a message type, a handover type, a handover cause, a source BSC ID, a target BSC ID, Radio Access Bearer (RAB) information and radio section-related information. The asynchronous MSC 220, having received the handover request message, transmits an
asynchronous message requesting handover to the HF 60 (using MAP Prep Handover Req) at step S 102. In this case, an extension container is added to the asynchronous message, and the asynchronous ID number MSISDN of the mobile communication terminal 10 is transmitted along with the asynchronous message. This message, as illustrated in FIG. 9, includes parameters such as an invoke ID, a target cell ID, a target RNC ID, and MSISDN.
Thereafter, the EF 60 requests the D-HLR 50 to transmit subscriber information with reference to the asynchronous subscriber information MSISDN received from the asynchronous MSC 220 (using Call Data Request) at step S 103. That is, the synchronous network identifiers MIN and ESN of the mobile communication terminal 10 are requested. At step S 103, the HF 60 may request the synchronous network identifier information of a subscriber from the D-HLR 50 using an asynchronous message (MAP SEND IMSI).
The D-HLR 50, having received the subscriber information request from the HF 60, searches the database, extracts the synchronous network identifier information MIN, ESN of the corresponding subscriber, and transmits the information to the HF 60 (using Call Data Req Ack) at step S 104. The HF 60, having received the information, directs the synchronous MSC 320 to perform handover (using Facilities Directive2) at step S 105, and the synchronous MSC 320 requests handover from the BSC/BTS 310 (using Handoff Request) at step S106. In this case, as illustrated in FIG. 10a, a synchronous network message (Call Data Request) requesting the synchronous network identifier information of the subscriber includes parameters, such as a billing H) and a digit (that is, MSISDN), and its response message (Call Data Req Ack) includes parameters such as ESN, MIN and MSCH).
Meanwhile, in the case of using an asynchronous message (MAP SEND IMSI) when requesting the synchronous network identifier information of a subscriber, the types of parameters included in the message are illustrated in FIG. 1 OB. As described above, before transmitting a handover direction message (Facilities
Directive2) to the synchronous MSC 320, the HF 60 creates a billing ID, includes the billing ID in the handover direction message (Facilities Directive2), and transmits the handover direction message (Facilities Directive2) with an internal MSC circuit ID (mterMSCCircuitID) included therein for each handover sectioα In this case, the billing ID includes the ID information of the synchronous MSC 320 to be connected to the asynchronous MSC 220. The BTS/BSC 310, having received the handover request from the MSC 320, transmits a NULL frame to the synchronous modem unit of the mobile communication terminal via a forward traffic channel, so that a forward channel is assigned at step S107. Thereafter, the BTS/BSC 310 transmits a response message (HandoffRequest Ack) for the handover request to the MSC 320 at step S 108. Furthermore, the MSC 320 transmits a response message (Facilities Directive2 Ack) for the handover direction to the HF 60 at step S 109, and the HF 60 transmits a response message (MAP Prep Handover Resp) for the handover request of step S 102 to the asynchronous MSC 220 at step SIlO. Accordingly, a relay line is set up between the asynchronous MSC 220 and the synchronous MSC 320.
The process of setting up the relay line between the asynchronous MSC 220 and the synchronous MSC 320 is described in more detail in the following. The HF 60 sets up a mapping relationship between a dedicated channel and a physical relay line, that is, a logical relay line setup identifier, sets this information as the internal MSC circuit ID (mterMSCCircuitDD) of the handover request message (Facilities Directive2), and transmits the set information to the synchronous MSC 320. When the response message (Facilities Directive2 Ack) is transmitted from the synchronous MSC 320, the relay line is set up between the asynchronous MSC 220 and the synchronous MSC 320. The handover request message (Facilities Directive2) transmitted and received between the DT 60 and the synchronous MSC 320, as illustrated in FIG. 11, includes parameters such as a billing ID, ESN, an internal MSC circuit ID, and MlN, and its response message (Facilities Directive2 Ack) includes parameters such as CDMA channel data and a CDMA channel list After the relay line has been set up between the MSCs as described above, the
asynchronous MSC 220 reports the completion of the assignment of resources for handover to the node B/RNC 210 (using IU Relocation Command) at step Sl 11. The node B/RNC 210, having received the report, requests the asynchronous modem unit of the mobile communication terminal 10 to perform handover (using Handover from UTRAN Command) at step Sl 12. In this case, the message (IU Relocation Command) reporting the completion of the assignment of resources, as illustrated in FIG. 12, includes parameters such as a message type, an RRC container, and an RAB list to be released.
Thereafter, the asynchronous modem unit of the mobile communication terminal transmits channel assignment information to the synchronous modem unit (using Channel Assignment) at step Sl 13, and the synchronous modem unit reports the completion of the connection to the synchronous mobile communication system to the asynchronous modem unit (using Call Connection) at step Sl 14. Thereafter, the HF 60 requests an access signal from the asynchronous MSC 220 (using MAP Process Access Signaling Req) at step Sl 15. The access signal includes an invoke ID, an application protocol data unit APDU and selected wireless resource information. The detailed parameter list is illustrated in FIG. 13.
Furthermore, the synchronous modem unit of the mobile communication terminal transmits frames and a preamble (Reverse Traffic Channel Frames or Traffic Channel Preamble) to the BTS/BSC 310 of the synchronous mobile communication system via a reverse traffic channel at step Sl 16, and reports the completion of the handover to the BTS/BSC 310 (using Handoff Completion Message) at step Sl 17. The BTS/BSC 310 trarismits a response signal for the report (using BS Ack Order) at step S118.
The BTS/BSC 310 reports the completion of the handover to the MSC 320 (using Handoff Complete) at step Sl 19, the MSC 320 reports the completion of the handover to the HF 60 (using Mobile On Channel) at step S 120, and the HF 60, having received the report, requests the asynchronous MSC 220 to release the connection (using MAP Send End Signal Req) at step S 121,
so that the connection between the asynchronous MSC 220 and the node B/RNC is released (using IU Release Command, IU Release Complete) at steps S122 and S123.
In this case, the handover completion message (Mobile On Channel), which is transmitted by the MSC 320 to the HF 60, is constructed as illustrated in FIG. 14, and the connection release request message (MAP Send End Signal Req), which is transmitted by the HF 60 to the asynchronous MSC 220, includes parameters illustrated in FIG. 15. Meanwhile, the messages (IU Release Command and IU Release Complete), which are transmitted and received between the asynchronous MSC 220 and the node B/RNC for release of the connection, are constructed as illustrated in FIGS. 16 and 17. A process of releasing a call after the completion of the handover of a mobile communication terminal, which was performing voice communication in the asynchronous mobile communication system, to the synchronous mobile communication system according to the above- described process is as follows. The call release may be requested by a subscriber's mobile communication terminal located in the area of the asynchronous mobile communication system, or by a subscriber's mobile communication terminal that was handed over to the area of the synchronous mobile communication system.
Although the call release request can be received from any party, the MSC 220 or 320, having received the call release request, transmits a call release request message (Facilities Release) to the HF 60, and the HF 60 responds to the call release request message (using Facilities Ack), so that a relay line set up between the MSCs is released. In this case, the call release request message (Facilities Release), as illustrated in FIG. 18, includes parameters, such as an internal MSC circuit ID, a release cause, a billing ID, and MIN, and its response message (Facilities Ack) includes parameters such as a billing ID.
In the present embodiment, the asynchronous MSC determines whether the requested handover is handover within the asynchronous mobile communication system or handover to the
synchronous mobile communication system based on the handover request of the RNC. If it is determined that the requested handover is handover to the synchronous mobile communication system, messages are exchanged with the MSC of the synchronous mobile communication system using the HF as a converter so as to accomplish the handover. For this purpose, the HF must previously store information about the synchronous mobile communication system in a database.
FIGS. 4 and 5 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to another embodiment of the present invention. The diagrams illustrate the handover method in the case where a mobile communication terminal moves to the area of a synchronous mobile communication system while in a reception alerting state in the area of an asynchronous mobile communication system.
For ease of description, the mobile communication terminals are classified as a calling mobile communication terminal 1 Oa and a called mobile communication terminal 1 Ob.
Referring to FIG.4, the mobile communication terminals 10a and 10b periodically measure the strength of a signal from the currently connected node B of the asynchronous mobile communication system 20 and the strength of a signal from an adjacent BTS (or node B), and report the measured signal strengths to the node B. In response to the attempt of the calling mobile communication terminal 10a at call origination in the area A of the asynchronous mobile communication system 20, when the called mobile communication terminal 1 Ob moves to an area C, overlapping the area B of the synchronous mobile communication system 30, in the case where the called mobile communication terminal 1 Ob is in a reception alerting state via a node B/RNC 210, the node B requests handover from the asynchronous MSC 220 via the RNC if the strength of the signal from the node B reported by the mobile communication terminal 10b is equal to or lower than a preset value.
Accordingly, the process of performing the handover of the called mobile communication terminal 10b between the asynchronous mobile communication system 20 and the synchronous
mobile communication system 30 is initiated via an HF 60. When an asynchronous MSC 220 and a synchronous MSC 320 are connected to each other via the HF 60 as a result of the completion of the handover, the reception alerting of the calling mobile communication terminal 10a causes the origination alerting of the called mobile communication terminal 10b via the BTS/BSC 310 of the synchronous mobile communication system 30.
The respective elements of the mobile communication terminal 10 and the mobile communication system, which are used to perform handover during the reception alerting, operate in a manner similar to that described in FIG.2.
FIG. 5 is a flowchart illustrating a handover method that is performed during the reception alerting of the mobile communication terminal. Step S201 of the node B requesting handover from the asynchronous MSC via the RNC and step S223 of releasing the connection between the asynchronous MSC and the node B/RNC after the completion of the handover are similar to the corresponding steps in FIG. 3.
However, in the present embodiment, when the asynchronous MSC 220, having received a handover request message, transmits an asynchronous message (MAP Prep Handover Req) requesting handover to the EOF 60 at step S202, the asynchronous message further includes the CDMA calling mode parameters of FIG. 19, in addition to the parameters of FIG. 9, thereby indicating that the mobile communication terminal performing handover is in a reception alerting state. Furthermore, in the present embodiment, in addition to the fact that the IDF 60 transmits a handover direction message (Facilities Directive2) with a billing DD and an internal MSC circuit ID (TnterMSCCircuit ID) for each handover section at step S205 of directing the synchronous MSC 320 to perform handover, the BDF 60 further includes information indicating that the mobile communication terminal performing handover is in a reception alerting state in the message, thereby causing a voice channel to be in a called state. For this purpose, one of the parameters of FIG. 11
that indicates a handover state is set as an identifier indicating a reception alerting state.
Meanwhile, when the called mobile communication terminal, having completed handover, makes a response after step S223 of the connection between the asynchronous MSC 320 and the node B/RNC 310 being released, the BTS/BSC 310 reports the response to the MSC 320 (using Connect) at step S224, and the MSC 320 provides notification of the response of the called mobile communication terminal by transmitting an Intersystem response message (Intersystem Answer) to the HF 60 at step S225. Subsequently, the HF 60 notifies the asynchronous MSC 220 of the response of the called mobile communication terminal by transmitting an access signal to the asynchronous MSC 220 at step S226 (MAP Process Access Signaling Req), and transmits a response message (Intersystem Answer Ack) for the intersystem response message to the MSC 320 at step
S227.
The intersystem response message (Intersystem Answer), as illustrated in FIG. 20, includes parameters such as an internal MSC circuit ED, MIN and ESN.
A process of releasing a call after a mobile communication terminal in a reception alerting state in the asynchronous mobile communication system has completed handover to the synchronous mobile communication system according to the above-described process and the called mobile communication terminal has responded, thus initiating communication between a calling party and a called party, is as follows.
The call release may be requested from a subscriber's mobile communication terminal located in the area of the asynchronous mobile communication system, or from a subscriber's mobile communication terminal that has undergone handover to the area of the synchronous mobile communication system.
Although the call release request may be received from any party, the MSC 220 or 320, having received the call release request, transmits a call release request message (Facilities Release) to the HF 60, and the HF 60 responds to the call release request message (using Facilities Ack), so mat a
relay line set up between the MSCs is released. In this case, the call release request message (Facilities Release), as illustrated in FIG. 18, includes parameters, such as an internal MSC circuit BD, a release cause, a billing BD, and MBNT, and its response message (Facilities Ack) includes parameters such as a billing ED. In the present embodiment, as the mobile communication terminal in a reception alerting state in the asynchronous area moves to the area of the synchronous network, the RNC requests handover from the asynchronous MSC, and the asynchronous MSC determines whether the requested handover is handover within the asynchronous mobile communication system or handover to the synchronous mobile communication system. Furthermore, if it is determined that the requested handover is handover to the synchronous mobile communication system, messages are exchanged with the MSC of the synchronous mobile communication system using the HF as a converter so as to accomplish the handover. In this case, notification of the fact that the handover target mobile communication terminal is in a reception alerting state is provided.
When the handover to the synchronous mobile communication system is completed and the mobile communication terminal placed in a reception alerting state responds, the synchronous MSC provides notification of the response of the mobile communication terminal to the alert by transmitting a system response message to the HF, thereby completing the handover.
FIGS. 6 and 7 are a conceptual diagram and a flowchart, respectively, illustrating a method of handover between asynchronous and synchronous networks according to still another embodiment of the present invention. The diagrams illustrate the handover method in the case where a mobile communication terminal moves to the area of a synchronous mobile communication system while in the state of waiting for the response of a called party after the origination of a call in the area of an asynchronous mobile communication system.
For ease of description, the mobile communication terminals are classified as a calling mobile communication terminal 1 Oa and a called mobile communication terminal 10b.
Referring to FIG. 6, the mobile communication terminals 10a and 10b periodically measure the strength of a signal from the currently connected node B of the asynchronous mobile communication system 20 and the strength of a signal from an adjacent BTS (or node B), and report the measured signal strengths to the node B. When the calling mobile communication terminal 1 Oa moves to an area C, overlapping the area B of the synchronous mobile communication system 30, in the case where the called mobile communication terminal 10b is in a reception alerting state via a node B/RNC 210, due to the attempt of the calling mobile communication terminal 10a at call origination, in the area A of the asynchronous mobile communication system 20, the node B requests handover from the asynchronous MSC 220 via the RNC if the strength of the signal from the node B received from the mobile communication terminal 1 Oa is equal to or lower than a preset value.
Accordingly, the process of performing handover of the calling mobile communication terminal 10a between the asynchronous mobile communication system 20 and the synchronous mobile communication system 30 is initiated via an HF 60. When an asynchronous MSC 220 and a synchronous MSC 320 are connected to each other via the DF 60 as a result of the completion of the handover, the calling mobile communication terminal 10a achieves a connection via the BTS/BSC 310 of the synchronous mobile communication system 30 and waits for a response from the called mobile communication terminal 10b.
The respective elements of the mobile communication terminal 10 and the mobile communication system, which are used to perform handover while waiting for a response to the origination of the call, operate in a manner similar to that described in FIG.2.
FIG. 7 is a flowchart illustrating a handover method that is performed while waiting for a response to the origination of a call of the mobile communication terminal. Step S301 of the node B requesting handover from the asynchronous MSC via the RNC and step S323 of releasing the connection between the asynchronous MSC and the node B/RNC after the completion of the handover are similar to the corresponding steps of FIG. 3.
However, in the present embodiment, when the asynchronous MSC 220, having received a handover request message, transmits an asynchronous message (MAP Prep Handover Req) requesting handover to the EOF 60 at step S202, the asynchronous message further includes the CDMA calling mode parameters of FIG. 19, in addition to the parameters of FIG. 9, thereby indicating that the mobile communication terminal performing handover is in the state of waiting for a response to the origination of the call.
Furthermore, in the present embodiment, in addition to the fact that the HF 60 transmits a handover direction message (Facilities Directive2) with a billing ID and an internal MSC circuit ID (InterMSCCircuit ID) for each handover section at step S205 of directing the synchronous MSC 320 to perform handover, the HF 60 further includes information indicating that the mobile communication terminal performing handover is in the state of waiting for a response to the origination of a call. For this purpose, one of the parameters of FIG. 11 that indicates a handover state is set as an identifier indicating the state of waiting for a response to the origination of a call.
Meanwhile, when the called mobile communication terminal 10b makes a response after step S323 of the connection between the asynchronous MSC 320 and the node B/RNC 310 being released, the node B/RNC 310, to which the called mobile communication terminal 1 Ob is connected, reports the response to the asynchronous MSC 220 at step S324 (using BICC or ISUP ANSWER), and the asynchronous MSC 220 transmits a forward access signal to the HF 60 at step S325 (MAP Forward Access Signaling Req). Accordingly, the HF 60 detects the response of the called mobile communication terminal and transmits an intersystem response message (Intersystem Answer) to the synchronous MSC 320 at step S326. Thereafter, the synchronous MSC 320 reports the response of the called mobile communication terminal to the BSC/BTS 310 at step S327 (Progress), and transmits a response message (Intersystem Answer Ack) for the intersystem response message to the HF 60 at step S328. The intersystem response message (Intersystem Answer), as illustrated in FIG. 20, includes
parameters such as an internal MSC circuit ID, MESf and ESN.
A process of releasing a call after the completion of the handover of the mobile communication terminal, which was in the state of waiting for a response in the asynchronous mobile communication system, to the synchronous mobile communication system, the response of the called mobile communication terminal, and the initiation of a call between a calling party and a called party according to the above-described process, is as follows.
The call release may be requested from a subscriber's mobile communication terminal located in the area of the asynchronous mobile communication system, or from a subscriber's mobile communication terminal that has performed handover to the area of the synchronous mobile communication system.
Although the call release request can be received from any party, the MSC 220 or 320, having received the call release request, transmits a call release request message (Facilities Release) to the HF 60, and the HF 60 responds to the call release request message (using Facilities Ack), so that a relay line set up between the MSCs is released. In this case, the call release request message (Facilities Release), as illustrated in FIG. 18, includes parameters such as an internal MSC circuit ID, a release cause, a billing ID, and MESf, and its response message (Facilities Ack) includes parameters such as a billing E).
In the present embodiment, as the mobile communication terminal, which is waiting for a response in the asynchronous area, moves to the area of the synchronous network, the RNC requests handover from the asynchronous MSC, and the asynchronous MSC determines whether the requested handover is handover within the asynchronous mobile communication system or handover to the synchronous mobile communication system. Furthermore, if it is determined that the requested handover is handover to the synchronous mobile communication system, messages are exchanged with the MSC of the synchronous mobile communication system using the DF as a converter so as to accomplish the handover. In this case, notification of the fact that the mobile
communication terminal being handed over is in the state of waiting for a response is provided.
When the handover to the synchronous mobile communication system is completed and the called mobile communication terminal responds, the synchronous MSC notifies the HF of the response of the called mobile communication terminal. Accordingly, the HF provides notification of the response of the called mobile communication terminal to alerting by transmitting an intersystem response message to the synchronous MSC, thereby completing the handover.
Those skilled in the art to which the above-described present invention pertains can appreciate that the present invention can be implemented in other specific forms without change of the technical spirit or essential features. Therefore, it should be understood that the above-described embodiments are illustrative in all respects, but not restrictive. The scope of the present invention is defined by the attached claims, rather than the detailed description. It should be appreciated that the meaning and scope of the claims and of all variations and modifications thereof based on Hie concept of equivalence are included in the scope of the present invention.
Industrial Applicability
As described above, the present invention allows handover to be achieved without the discontinuation of service in the case where an asynchronous mobile communication system overlaps a synchronous mobile communication system and a DBDM mobile communication terminal moves from the area of the asynchronous mobile communication system to the area of the synchronous mobile communication system, thereby overcoming the difference in service between the network generations and providing high-quality service.
Furthermore, it is not necessary to construct an asynchronous mobile communication system over an excessively wide area, so that the investment cost required for the design of the asynchronous mobile communication system can be reduced.