KR100993454B1 - Dual Band/Dual Mode Mobile Communication Terminal and Control Method Thereof - Google Patents

Abstract

The present invention relates to a mobile communication terminal supporting a dual band / dual mode capable of smooth roaming in a synchronous mobile communication network and an asynchronous mobile communication network, and a control method thereof, wherein the mobile communication terminal transmits and receives radio waves to and from an asynchronous mobile communication network and a synchronous mobile communication network. An antenna for the device, an asynchronous radio for performing asynchronous communication with the asynchronous mobile communication network through the antenna, a synchronous radio for performing synchronous communication with the synchronous mobile communication network through the antenna, the synchronous radio and an asynchronous radio device. It includes a common module for providing a common resource in the wireless communication with the synchronous mobile communication network and the asynchronous mobile communication network through, and set the initial access mobile communication network when the power is turned on, and after receiving the setting waits for the signal of the mobile communication network, Receive signal and register location to mobile network By doing so, not only smooth handover can be performed between the asynchronous mobile communication network and the synchronous mobile communication network, but also the mobile terminal terminates the call in the synchronous mobile communication network and enters the handover to the asynchronous mobile communication network. By doing this, it is possible to prevent unnecessary network resource waste due to handover during a call.

Description

Dual Band / Dual Mode Mobile Communication Terminal and Control Method Thereof}

1 is a block diagram illustrating a connection between a mobile communication terminal and a mobile communication network according to the present invention;

2 is a block diagram for explaining the configuration of a mobile communication terminal according to the present invention;

3 is a block diagram for explaining the configuration of a mobile communication terminal according to the present invention;

4 is a block diagram illustrating a platform structure of a mobile communication terminal according to the present invention;

5 is a flowchart illustrating the control of a mobile communication terminal according to the present invention;

6 is an explanatory diagram for explaining the state of a mobile communication terminal in an asynchronous mobile communication network and a synchronous mobile communication network in the present embodiment;

7 is a flowchart illustrating a handover procedure of a mobile communication terminal according to the present invention.

<Brief description of the main parts of the drawings>

100: asynchronous mobile communication network 200: synchronous mobile communication network

400: mobile communication terminal 410: antenna

420: asynchronous wireless device 430: synchronous wireless device                 

440: common module 443: main processor

The present invention relates to a mobile communication terminal, and more particularly, to a mobile communication terminal supporting a dual band / dual mode capable of smooth roaming in a synchronous mobile communication network and an asynchronous mobile communication network, and a control method thereof.

Currently, mobile communication service technology can be broadly classified into asynchronous service environment centering on Europe and synchronous service centering on North America. In addition, the IMT-2000 service is evolving around North America and Europe as a new mobile communication technology standard for delivering packets at high speed.

Synchronous IMT-2000 service is evolving into CDMA2000 1x, CDMA2000 1x EV-DO, and asynchronous IMT-2000 service is evolving as WCDMA UMTS service. In such an environment, the problem of roaming between synchronous and asynchronous is emerging as a current issue. Accordingly, a terminal supporting dual band / dual mode is required to smoothly roam a synchronous mobile network and an asynchronous mobile communication network.

Accordingly, an object of the present invention is to provide a mobile communication terminal supporting a dual band / dual mode capable of smooth roaming in a synchronous mobile network and an asynchronous mobile communication network, and a control method thereof.

A mobile communication terminal supporting the dual band / dual mode according to the present invention for achieving the above object, in the mobile communication terminal capable of performing wireless communication with an asynchronous mobile communication network and a synchronous mobile communication network, the asynchronous mobile communication network And an antenna for transmitting and receiving radio waves with a synchronous mobile communication network, an asynchronous wireless device for performing asynchronous communication with the asynchronous mobile communication network through the antenna, and a synchronous wireless device for performing synchronous communication with the synchronous mobile communication network through the antenna. And a common module for providing common resources in wireless communication with the synchronous mobile communication network and the asynchronous mobile communication network through the synchronous radio device and the asynchronous radio device.

In addition, the control method of the mobile communication terminal supporting the dual band / dual mode according to the present invention, the first step of setting the initial access mobile communication network when the power is turned on, after receiving the signal of the mobile communication network after setting in the first step In step 2, if the signal is received in step 2, characterized in that it comprises a third step of performing a location registration to the mobile communication network.

Hereinafter, with reference to the accompanying drawings to describe the present invention in detail.

1 is a block diagram illustrating the configuration of a synchronous and asynchronous mobile communication network according to the present invention.

Referring to FIG. 1, a WCDMA network 100 that is an asynchronous network includes a wireless station 101 that performs wireless communication with a mobile communication terminal 400 and a wireless station controller (hereinafter referred to as 'RNC') that controls the wireless station 101. 102, a Serving GPRS Service Node (hereinafter referred to as "SGSN") 103 connected to the RNC 102 to manage mobility of the mobile communication terminal 400, and a GPRS network An asynchronous communication network data service gateway node (hereinafter referred to as 'GGSN') 106, which is a relay that performs the packet service control and packet data transfer through 105, is included.

In addition, an exchanger (hereinafter referred to as 'MSC') 104 which performs call exchange is connected to the RNC 102, and the MSC 104 is a number seven signal network (No. 7 signal network) for signal exchange. 107 is connected. The number seven signal network 107 has a short message service center (hereinafter referred to as SMSC) 108 for serving a short message, and a home location register (hereinafter referred to as 'HLR') for managing location information of subscribers. 110 is connected.

Meanwhile, the CDMA2000 network 200, which is a synchronous network, includes a base station (hereinafter referred to as 'BTS') 201 that performs wireless communication with the mobile communication terminal 400, and a base station controller (hereinafter, referred to as 'BTS'). BSC ') 202, a Packet Data Service Node (hereinafter referred to as' PDSN') 204 connected to the BSC 202 and serving packet data, and the PDSN 204. A Data Core Network (DCN) 209 that is connected and performs an Internet access service, and an exchanger (hereinafter referred to as MSC) connected to the BSC 202 to perform an exchange ( 203).

The MSC 203 is connected with a number seven signal network (No. 7 signal network) 205 for signal exchange. The number seven signal network 205 includes a short message service center (hereinafter referred to as 'SMSC') 206 that serves a short message, and a home location register (hereinafter referred to as 'HLR') to manage location information of the subscriber. 208 is connected.

In the present embodiment, the synchronization network 200 and the asynchronous network 100 have HLRs 110 and 208 for managing subscriber information and location information, respectively, but using one HLR (dual stack home location register). By doing so, the synchronization network 200 and the asynchronous network 100 may share subscriber information and location information.

2 is a block diagram illustrating a configuration of a dual band mobile communication terminal according to the present invention.

Referring to FIG. 2, the dual band mobile communication terminal 400 according to the present invention supports both synchronous mobile communication and asynchronous mobile communication and has respective protocol stacks.

The mobile communication terminal 400 according to the present invention is broadly divided into an antenna 410 for transmitting and receiving radio waves with the synchronous mobile communication network 200 and the asynchronous mobile communication network 100, and a synchronous radio device 430 for synchronous communication. , Asynchronous radio 420 for asynchronous communication, and a common module 440 for providing common resources in synchronous and asynchronous communication.

The synchronous radio device 430 includes a synchronous radio transmitter 432 for radio transmission, a synchronous radio receiver 433 for radio reception, and a synchronous modem unit 434. The synchronous radio transmitter 432 and One side of the synchronous radio receiver 433 is connected to the antenna 410 through a duplexer 431, and the other side is connected to the synchronous modem unit 434.

In addition, the asynchronous radio device 420 also includes an asynchronous radio transmitter 422 for radio transmission, an asynchronous radio receiver 423 for radio reception, and an asynchronous modem unit 424. The asynchronous radio transmitter 422 And one side of the asynchronous radio receiver 423 is connected to the antenna 410 through the duplexer 421 and the other side is connected to the asynchronous modem unit 424.

3 is a block diagram illustrating a configuration of a common module of a mobile communication terminal according to the present invention.

Referring to FIG. 3, the common module 440 of the mobile communication terminal according to the present invention includes a plurality of dual devices connected to the modem units 424 and 434 of the synchronous radio device 430 and the asynchronous radio device 420. Dual Port RAM (hereinafter referred to as DPRAM) 441 and 442 and the DPRAM 441 and 442 are connected to perform overall control and application execution of synchronous and asynchronous communication of the mobile communication terminal 400. A main processor 443. The main processor 443 includes a memory 444 for storing data, an I / O device 445 for connecting a peripheral device, and a power control module (hereinafter referred to as 'PWM') 446 for power control. Connected.

4 is a block diagram illustrating a platform configuration of a mobile communication terminal according to the present invention.

Referring to Figure 4, the platform of the mobile communication terminal according to the present invention, the operation control of the mobile communication terminal supporting the wireless Internet environment and call processing through the modem unit of the synchronous wireless device 430 or asynchronous wireless device 420 And a main processor 443 and an operating system (OS) module 510. The main processor 443 is connected to an operating system module 510 and is operated. The operating system module 510 is an operating system of a mobile communication terminal, for example, a Real Time Execution (REX) and a Pioneer Server OS (PSOS). It can be an operating system.

In addition, the main processor 443 of the platform of the mobile communication terminal 400 includes a driver module 448, a memory 444 for data storage, an I / O device 445 and a voice for connecting peripheral devices. Codec 447 is connected.

The I / O device 445 is connected to a key input unit (not shown) for receiving a key command from the user, and peripheral devices such as a sound output unit (not shown) and a display unit (not shown). Receives a key input from the user and transmits it to the main processor 443. The sound output unit outputs sound through the speaker of the terminal under the control of the main processor 443. The display unit includes all the operation information of the terminal. Perform a visual display.

In addition, the platform according to the present invention includes a control module 520 having a control function including mobility, an application module 530 and a user interface module 540 for executing an application.

The control module 520 includes a mobility management module 521 for managing mobility, a session control module 522 for managing call connection and session, and a resource control module 523 for managing system resources. .                     

According to the platform of the mobile communication terminal according to the present invention having the above configuration, the main processor 443 selectively activates the synchronous radio 430 and the asynchronous radio 420 according to the operating system of the operating system module 510. / Set to parking mode, which will be described in detail below.

5 is a flowchart illustrating the control of a mobile communication terminal according to the present invention.

Referring to FIG. 5, in the mobile communication terminal according to the present invention, when the initial power is turned on (S10), the main processor 443 preferentially selects asynchronous communication (S20). Accordingly, the main processor 443 sets the synchronous radio 430 to the parking mode and sets the asynchronous radio 420 to an active state.

In operation S20, the main processor 443 sets the asynchronous radio device 420 to an activated state, and then determines whether a signal from the asynchronous mobile communication network 100 is received (S30).

If it is determined in step S30 that a signal of the asynchronous mobile communication network 100 is not received, the main processor 443 determines whether a preset reference time has elapsed (S31). If it is determined in step S31 that the preset reference time has not elapsed, the main processor 443 waits for the signal of the asynchronous mobile communication network 100 to be received.

If it is determined in step S30 that a signal of the asynchronous mobile communication network 100 has been received, the main processor 443 performs PLMN and cell selection according to the strength of the signal transmitted from the wireless station 101 of the asynchronous mobile communication network 100. (S40 and S50). The main processor 443 performs location registration by transmitting a registration request message to the asynchronous mobile communication network 100 (S60). In step S60, the registration request message is transmitted to the asynchronous mobile communication network 100 through the wireless station 101, and location registration is performed to the HLR 110 through the MSC 104 of the asynchronous mobile communication network 100.

On the other hand, if it is determined in step S31 that the preset reference time has elapsed, the main processor 443 sets the currently active asynchronous radio 420 to the parking mode and sets the synchronous radio 430 in the parking mode. It is set to the active state and connected to the synchronous mobile communication network 200 (S32).

The main processor 443 transmits a registration request message to the synchronous mobile communication network 200 to perform location registration with the HLR 208 (S33), and waits in an idle state (S34).

In the above-described embodiment of FIG. 5, the asynchronous mobile communication network 100 is preferentially selected when the power is first turned on, but the user may select the synchronous 200 or the asynchronous mobile communication network 100 through the user interface.

FIG. 6 is an explanatory diagram for explaining a state of a mobile communication terminal in an asynchronous mobile communication network and a synchronous mobile communication network in this embodiment.

Referring to FIG. 6, in this embodiment, the area of the asynchronous mobile communication network 100 is included in the area of the synchronous mobile communication network 200. In the area of the asynchronous mobile communication network 100, the synchronous wireless device (CDMA2000) 430 is set to the parking mode, and the asynchronous wireless device (WCDMA) 420 is set to the active state. Further, in the area of the synchronous mobile communication network 200, the asynchronous radio (WCDMA) 420 is set to the parking mode and the synchronous radio (CDMA2000) 430 is set to the active state.

The handover procedure between the asynchronous mobile communication network and the synchronous mobile communication network of the mobile communication terminal according to the above process will be described in detail below.

7 is a flowchart illustrating a handover procedure of a mobile communication terminal according to the present invention.

Referring to FIG. 7, when the mobile communication terminal is located in the area of the asynchronous mobile communication network 100, the main processor 443 activates the asynchronous radio 420 and sets the synchronous radio 430 to the parking mode ( S110). After the step S110, the main processor 443 determines whether the mobile communication terminal 400 moves from the area of the asynchronous mobile communication network 100 to the area of the synchronous mobile communication network 200 (S120).

If it is determined in step S120 that the mobile communication terminal 400 moves from the area of the asynchronous mobile communication network 100 to the area of the synchronous mobile communication network 200, the main processor 443 sets the asynchronous radio device 420 to the parking mode. Then, by activating the synchronous radio 430, handover to the synchronous mobile communication network 200 is performed (S130). Accordingly, the mobile communication terminal 400 performs wireless communication with the synchronous mobile communication network 200 through the synchronous wireless device 430.

After operation S130, the main processor 443 determines whether the mobile communication terminal 400 moves from the current synchronous mobile communication network 200 to the area of the asynchronous mobile communication network 100 (S140).

If it is determined in step S140 that the mobile communication terminal 400 enters the area of the asynchronous mobile communication network 100 from the area of the synchronous mobile communication network 200, the main processor 443 may determine that the mobile communication terminal 400 is currently in the synchronous mobile communication network. In operation S150, it is determined whether the call is in progress.

If it is determined in step S150 that the call is not busy, the main processor 443 performs the handover to the asynchronous mobile communication network 100 by setting the asynchronous radio 420 to active and setting the synchronous radio 430 to the parking mode. (S160).

However, if it is determined in step S150 that the call is busy, the main processor 443 determines whether the call is terminated (S151). If it is determined in step S151 that the call has not ended, the main processor 443 waits until the call ends. If it is determined that the call has ended, the main processor 443 controls the synchronous radio 430 in the idle mode (S152). ). The main processor 443 then sets the asynchronous radio 420 in the current parking mode to active, and sets the synchronous radio 430 in the idle mode to the parking mode to handover to the asynchronous mobile communication network 100. To perform (S160).

As described above, when the mobile communication terminal 400 is out of the area of the current asynchronous mobile communication network 100, the asynchronous radio device 420 is placed in the parking mode regardless of whether a call is made in the current asynchronous mobile communication network 100. By activating the synchronous radio 430, handover is immediately performed to the area of the synchronous mobile communication network 200.                     

However, when the mobile communication terminal 400 is located in the area of the synchronous mobile communication network 200 and enters the area of the asynchronous mobile communication network 100, the handover time is determined according to whether the current mobile communication terminal 400 calls through the synchronous mobile communication network 200. Done. That is, when the mobile communication terminal 400 enters the area of the asynchronous mobile communication network 100 when the call is in progress through the synchronous mobile communication network 200, the handover is not immediately performed. When the call ends, handover is performed from the synchronous mobile communication network 200 to the asynchronous mobile communication network 100.

This is because the area of the asynchronous mobile communication network 100 is included in the area of the synchronous mobile communication network 200 as described above, and the call is terminated in the synchronous mobile communication network 200 and the handover to the asynchronous mobile communication network 100 is terminated. By doing so, unnecessary network resource waste due to handover during a call can be prevented.

As described above, according to the mobile communication terminal and the control method supporting the dual band / dual mode according to the present invention, not only smooth handover between the asynchronous mobile communication network and the synchronous mobile communication network, but also during a call in the synchronous mobile communication network When entering the asynchronous mobile communication network area, the call is terminated in the synchronous mobile communication network and the handover is performed to the asynchronous mobile communication network, thereby preventing unnecessary waste of resources of the network due to handover during the call.

Claims (14)

A mobile communication terminal capable of performing wireless communication with an asynchronous mobile communication network and a synchronous mobile communication network, An antenna for radio wave transmission and reception with the asynchronous mobile communication network and the synchronous mobile communication network; An asynchronous wireless device for performing asynchronous communication with the asynchronous mobile communication network through the antenna, A synchronous wireless device for performing synchronous communication with the synchronous mobile communication network through the antenna; And a common module for providing a common resource in the wireless communication with the synchronous mobile communication network and the asynchronous mobile communication network through the synchronous radio device and the asynchronous radio device. The method of claim 1, The asynchronous radio apparatus is connected to an asynchronous radio transmitter for radio transmission to the asynchronous mobile communication network, an asynchronous radio receiver for radio reception from the asynchronous mobile communication network, the asynchronous radio transmitter and an asynchronous radio receiver to perform asynchronous communication. And a duplexer for providing a double connection between the asynchronous modem and the asynchronous wireless receiver and the antenna, and the asynchronous modem for controlling the mobile communication terminal. The method of claim 1, The synchronous radio apparatus is connected to a synchronous radio transmitter for radio transmission to the synchronous mobile communication network, a synchronous radio receiver for radio reception from the synchronous mobile communication network, the synchronous radio transmitter and a synchronous radio receiver to perform synchronous communication. And a duplexer for providing a plural connection between the synchronous radio transmitter and the synchronous radio receiver and the antenna. 10. A mobile communication terminal supporting a dual band / dual mode. The method according to claim 2 or 3, The common module includes a plurality of dual port RAMs connected to the synchronous modem unit and the asynchronous modem unit, and a main processor connected to the dual port RAMs to perform overall control of synchronous and asynchronous communication of a mobile communication terminal and to execute an application. And a memory for performing data storage connected to the main processor, an I / O device for connecting a peripheral device, and a power control module for power control. Mobile communication terminal. The method of claim 4, wherein The main processor activates the asynchronous radio device upon initial power-up, and the synchronous radio device controls the dual band / dual mode, characterized in that the parking mode is controlled. The method of claim 5, The main processor may set the asynchronous radio to a parking mode and activate the synchronous radio when no signal is received from the asynchronous mobile communication network for a preset reference time after activating the asynchronous radio according to the initial power-on. A mobile communication terminal supporting dual band / dual mode. The method of claim 4, wherein When the mobile communication terminal is located in an area of the asynchronous mobile communication network and leaves the area of the asynchronous mobile communication network, the main processor sets the asynchronous radio device to the parking mode regardless of whether a call is currently made in the asynchronous mobile communication network. A mobile communication terminal supporting dual band / dual mode, wherein the handover is performed immediately to the area of a synchronous mobile communication network by activation. The method of claim 4, wherein When the mobile communication terminal is located in an area of a synchronous mobile communication network and enters an area of an asynchronous mobile communication network, the main processor determines a handover time according to whether a call is made through the current synchronous mobile communication network. Mobile terminal that supports. The method of claim 8, The area of the asynchronous mobile communication network is located in the area of the synchronous mobile communication network, When the mobile communication terminal enters the area of the asynchronous mobile communication network during a call from the current synchronous mobile communication network, the main processor activates the asynchronous wireless device in the idle mode after the call ends and controls the synchronous wireless device to the parking mode to the asynchronous mobile communication network. A mobile communication terminal supporting dual band / dual mode, characterized in that to perform handover. An antenna for radio wave transmission and reception with an asynchronous mobile communication network and a synchronous mobile communication network, an asynchronous wireless device for performing asynchronous communication with the asynchronous mobile communication network through the antenna, and performing synchronous communication with the synchronous mobile communication network through the antenna. A synchronous radio device, a main processor that performs control during radio communication with the synchronous / asynchronous mobile communication network through the synchronous and asynchronous radio devices, and a common module for providing a common resource. In a control method of a mobile communication terminal capable of performing wireless communication in a mobile communication network, A first step in which the main processor sets an initial access mobile communication network when the power is turned on; Step 2 in which the main processor waits to receive the signal of the mobile communication network after setting in step 1, And receiving a signal in step 2, wherein the main processor registers a location with a corresponding mobile communication network. 3. The method of claim 10, The initial access mobile communication network in the first step is an asynchronous mobile communication network, and the main processor sets the synchronous radio device to the parking mode, activates the asynchronous radio device, and performs the second step. Control method of a mobile communication terminal that supports the. The method of claim 11, After receiving the signal of the asynchronous mobile communication network in step 2 and performing the location registration in step 3, When the mobile communication terminal leaves the area of the asynchronous mobile communication network, the main processor supports dual band / dual mode by performing the handover by setting the asynchronous wireless device to the parking mode and activating the synchronous wireless device. Control method of a mobile communication terminal. The method of claim 11, And setting, by the main processor, the asynchronous wireless device to a parking mode and activating the synchronous wireless device when the reception waiting time has elapsed in the second step. And the main processor performs location registration to the synchronous mobile communication network in step 3 when the signal of the synchronous mobile communication network is received through the synchronous wireless device. The method of claim 13, The area of the asynchronous mobile communication network is located in the area of the synchronous mobile communication network, In step 3, when the mobile communication terminal enters an area of the asynchronous mobile communication network after registering a location in the synchronous mobile communication network, the main processor determines whether the current mobile communication terminal is making a call through the synchronous mobile communication network; If it is determined that the call is made, the main processor waits for handover; When the mobile communication terminal enters an idle mode after the call is terminated, the main processor includes performing a handover to an asynchronous mobile communication network by setting the synchronous radio to a parking mode and activating the asynchronous radio. A control method of a mobile communication terminal supporting dual band / dual mode.

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