KR101101041B1 - Mode Switching Method of Multi-mode Multi-band Mobile Communication Terminal between CDMA Network and WCDMA Network - Google Patents

Abstract

The present invention relates to a synchronous-asynchronous mode switching method of a multimode-multiband mobile communication terminal. When the synchronous-asynchronous mode switching command is received from a synchronous mobile communication network, the asynchronous signal is switched to an asynchronous signal. Searching for a first step; A second step of determining whether to search for an asynchronous signal and whether to register a location on an asynchronous mobile communication network; A third step of switching to a synchronous mode when the asynchronous signal is not searched or the location registration to the asynchronous mobile communication network is not performed; Determining whether the access base station has been changed, and comparing the base station change count with the reference base station change count M; If the base station change count is more than the base station change count (M), the asynchronous signal search period is initialized and fed back to the first step.If the base station change count is smaller than the reference base station change count (M), the asynchronous signal search count (n) is asynchronous. A fifth step of determining whether the signal has a maximum number of search times N _max ; If the asynchronous signal search frequency (n) is more than the asynchronous signal maximum search frequency (N _max ), the asynchronous signal search process is terminated by maintaining the synchronous mode.If the search frequency (n) is less than the maximum search frequency (N _max ), the search frequency determining a asynchronous signal search period according to (n) and driving a timer; A seventh step of returning to the first step when the timer passes the asynchronous signal search period; There is a technical feature made to include.

Description

Mode Switching Method of Multi-mode Multi-band Mobile Communication Terminal between CDMA Network and WCDMA Network}

1 is a configuration diagram of a mobile communication system applied to the present invention;

2 is a configuration diagram for explaining the configuration of a multi-mode multi-band mobile communication terminal according to the present invention;

3 is a configuration diagram for explaining the configuration of a common module of a multi-mode multi-band mobile communication terminal according to the present invention;

4 is a conceptual diagram illustrating a mode switching method of a multi-mode multi-band mobile communication terminal according to the present invention;

5 is a flowchart illustrating a mode switching process from a synchronous mode to an asynchronous mode of a multi-mode multi-band mobile communication terminal according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: asynchronous mobile communication network 20: synchronous mobile communication network

30: boundary area 40: asynchronous out of service area

100: asynchronous mobile communication system 200: synchronous mobile communication system

300: Internet 400: Multimode-Multiband Mobile Communication Terminal

420: asynchronous radio 430: synchronous radio

440: common module 443: main processor

The present invention relates to a method of switching between synchronous and asynchronous modes of a multimode-multiband mobile communication terminal. More particularly, the present invention relates to asynchronous signals at a predetermined time period when a connection is switched from a synchronous mobile communication network to an asynchronous mobile communication network. Search for asynchronous signals by initializing the asynchronous signal search cycle according to the number of times of access base station change to prevent the delay of asynchronous signal acquisition in the asynchronous mobile communication network. The present invention relates to a method of switching between synchronous and asynchronous modes of a multimode-multiband mobile communication terminal that does not continue unnecessarily.

The mobile communication service has been continuously developed starting from the low quality voice call-oriented first generation mobile communication service provided by the analog cellular Advanced Mobile Phone Service (AMPS), which has been in service since the late 1980s.

In the second generation mobile communication service, improved voice call and low speed (14.4 Kbps) data service provided by digital cellular Global System for Mobile (GSM), Code Division Multiple Access (CDMA), and Time Division Multiple Access (TDMA) were possible. . In addition, in the 2.5G mobile communication service, the PCS (Personal Communication Service), which can be used around the world in addition to securing frequencies of several GHz bands, has been developed to enable improved voice call and low speed (144 Kbps) data service.

Mobile communication network for mobile communication service up to 2.5 generations includes various communication equipment such as user terminal, base station transmitter, base station controller, mobile switching center, home location register (HLR), visitor location register (VLR), etc. Is installed.

The 3G mobile communication service is classified into asynchronous WCDMA system proposed by 3GPP (Generation Partnership Project) and synchronous CDMA-2000 system proposed by 3GPP2. In particular, the WCDMA system is a wireless protocol recommended by IMT-2000, and many telecommunication service providers around the world are providing or preparing to provide services.

WCDMA system has the advantage of high call quality and spread spectrum method, which is suitable for large data transmission, and is supported by most countries by supporting high mobility. The 3GPP, which is composed of many organizations in China and other countries, is continuously developing technical specifications for WCDMA.

Recently, due to the advantages of the WCDMA system described above, even in countries such as Korea, the United States, and China, which basically provide the CDMA-2000 service, which is a synchronous mobile communication network, a WCDMA network, which is an asynchronous mobile communication network, begins to provide WCDMA service. For this purpose, a mobile communication terminal supporting both a synchronous mobile network and an asynchronous mobile communication network is required, and a multimode-multiband mobile communication terminal has emerged.

Multimode includes synchronous mode and asynchronous mode, and multiband includes second generation mobile communication service using 800 MHz frequency band, 2.5 generation mobile communication service using 800 MHz or 1.8 GHz frequency band, and a frequency band of approximately 2 GHz. 3 generation mobile communication service using and 4 generation mobile communication service to be serviced in the future.

When the multi-mode multi-band mobile communication terminal moves from the area of the synchronous mobile communication network to the overlay area of the asynchronous mobile communication network, it is necessary to switch between the synchronous mode and the asynchronous mode.

However, when the mobile communication terminal enters the overlay area during the mode switching, the mode switching is performed immediately. Therefore, if there is a problem in the asynchronous mobile communication network and the location registration is impossible or the asynchronous signal is not in the area, the ping-pong phenomenon occurs. There has been a problem that the terminal is incapable of continuously making calls, and there are problems such as waste of radio resources and power consumption of the mobile communication terminal due to frequent location registration attempts.

The present invention has been made to solve the above-described problem, so that the multi-mode multi-band mobile communication terminal can automatically minimize the ping-pong (PING-PONG) phenomenon that occurs when performing the mode switching between the synchronous and asynchronous, Search the asynchronous signal by increasing the signal search period in the area where the asynchronous signal is not searched, but initialize the signal search period according to the number of times of access base station of the mobile communication terminal so that the fast mode switching to the asynchronous mobile communication network is performed. There is a technical problem of providing a method of switching between synchronous and asynchronous modes of a multimode-multiband mobile communication terminal to provide a service of a synchronous mobile communication network when the asynchronous signal is not searched for a long time.

The object of the present invention is to provide a synchronous-asynchronous mode switching method of a multi-mode multiband mobile communication terminal including a synchronous modem unit for communication with a synchronous mobile communication network and an asynchronous modem unit for communication with an asynchronous mobile communication network. The mobile communication terminal is a system parameter of an asynchronous mobile communication network for asynchronous signal search including a reference base station change count (M) for determining whether the terminal is moved and asynchronous signal search limit (N _max ) for limiting asynchronous signal search. A first step of retrieving an asynchronous signal by switching to an asynchronous mode when receiving a synchronous-asynchronous mode switching command from a synchronous mobile communication network in a boundary area having a value and overlapping areas of the asynchronous mobile communication network and a synchronous mobile communication network; ; Determining a result of the asynchronous signal search, whether to search for an asynchronous signal, and whether to register a location in an asynchronous mobile communication network; A third step of switching the communication mode of the mobile communication terminal to the synchronous mode when the asynchronous signal is not found or the location registration to the asynchronous mobile communication network is not performed; Determining whether an access base station has changed due to the movement of the mobile communication terminal, and updating the base station change frequency according to the result, and comparing the base station change frequency with the reference base station change frequency (M); If the base station change frequency is more than the reference base station change frequency (M), the asynchronous signal search period is initialized and fed back to the first step, and if the base station change frequency is smaller than the reference base station change frequency (M), the asynchronous signal search frequency ( a fifth step of determining whether n) is equal to or greater than the maximum number of asynchronous search times N _max ; If the asynchronous signal search frequency (n) is greater than or equal to the asynchronous signal maximum search frequency (N _max ), the asynchronous signal search process is terminated by maintaining the synchronous mode, and the asynchronous signal search frequency (n) is the asynchronous signal maximum search frequency (N _max ). Determining the asynchronous signal search period according to the number of asynchronous signal search times n, and driving a timer if smaller; A seventh step of returning to the first step when the timer passes the asynchronous signal search period; It is achieved by the synchronous-asynchronous mode switching method of a multi-mode multi-band mobile communication terminal comprising a.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a mobile communication system applied to the present invention.

As shown, the asynchronous mobile communication system 100 includes a radio station 101 performing radio communication with the mobile communication terminal 400, a radio station controller (RNC) 102 controlling the radio station 101, and the RNC. The packet service control and the packet data transmission are performed through a Serving GPRS Support Node (SGSN) 103 connected to the 102 to manage mobility of the mobile communication terminal 400 and a General Packet Radio Service 105. The gateway device includes a gateway GPRS support node (GGSN) 106.

In addition, the RNC 102 is connected to an exchange (MSC) 104 that performs call exchange, and the MSC 104 is connected to a No. 7 signal network 107 for signal exchange. The No. 7 signal network 107 is connected to a short message service center (SMSC) 108 for serving a short message and a home location register (HLR) 109 for managing location information of a subscriber.

Meanwhile, the synchronous mobile communication system 200 includes a base station (BTS) 201 for performing wireless communication with the mobile communication terminal 400, a base station controller (BSC) 202 for controlling the BTS 201, and the BSC. A packet data service node (PDSN) 204 connected to 202 to service packet data, a data core network DCN 208 connected to the PDSN 204 to perform an Internet access service, and the BSC 202; And an exchanger (MSC) 203 connected with and performing call exchange.

The MSC 203 is connected to a No. 7 signal network 205 for signal exchange, and a No. 7 signal network 205 has a Short Message Service Center (SMSC) 206 for serving a short message, and a subscriber's location. A home location register (HLR) 207 for managing information is connected.

Meanwhile, in the above description, the synchronous mobile communication system 200 and the asynchronous mobile communication system 100 have HLRs 109 and 207 for managing subscriber information and location information, respectively. The stack home location register may be used to allow the synchronous mobile communication network 200 and the asynchronous mobile communication network 100 to share subscriber information and location information.

In this case, when the mobile communication terminal 400 using the service in the synchronous mobile communication network moves to the asynchronous mobile communication network and enters the synchronous-asynchronous mode switching cell area, that is, the boundary area between the asynchronous mobile communication network and the synchronous mobile communication network, The BTS 201 of the synchronous mobile communication network located in the border region includes a parameter for mode switching in a base station identifier (BASE ID), and transmits it to the mobile communication terminal to instruct mode switching between synchronous and asynchronous. Accordingly, the mobile communication terminal receives the base ID information of the BTS 201, and if the information includes a parameter for mode switching, the mobile communication terminal performs switching from synchronous mode to asynchronous mode.

The mode switching parameter is set to bits in a predetermined order from the most significant bit (MSB) of the base ID (for example, when moving to the boundary area of the synchronous mobile network and the asynchronous mobile communication network, the second bit is set to 1). Parameter to indicate the boundary area where the asynchronous mobile network and the synchronous mobile network are overlaid.

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

As shown, the multi-mode multi-band mobile communication terminal 400 according to the present invention is to support both a synchronous mobile communication service and an asynchronous mobile communication service, and has a respective protocol stack for this.

The mobile communication terminal 400 includes an antenna 410 for transmitting and receiving radio waves between a synchronous mobile communication network and an asynchronous mobile communication network, a synchronous radio 430 for synchronous communication, an asynchronous radio 420 for asynchronous communication, synchronous and It is configured to include a common module 440 for providing a common resource in asynchronous communication.

The synchronous radio 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 The synchronous radio receiver 433 is connected to the antenna 410 through the duplexer 431, and is also connected to the synchronous modem unit 434.

In addition, the asynchronous radio 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, and the asynchronous radio transmitter 422. The asynchronous wireless receiver 423 is connected to the antenna 410 through the duplexer 421, and is connected to the asynchronous modem unit 424.

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

As shown, the common module 440 of the multi-mode multi-band mobile communication terminal according to the present invention, each modem unit 424 of the synchronous radio 430 and the asynchronous radio 420 described with reference to FIG. A plurality of dual port RAMs (DPRAM) 441 and 442 connected to the 434, and the DPRAM 441 and 442, are used to control the overall control and application execution of the synchronous and asynchronous communication of the mobile communication terminal 400. A main processor 443 that performs.

The main processor 443 is connected to a memory 444 for data storage, an I / O device 445 for connecting a peripheral device, and a power control module (PWM) 446 for power control.

The mobile communication terminal 400 may perform communication in an asynchronous mobile communication network and a synchronous mobile communication network, and perform an asynchronous dedicated communication mode (WCDMA only) that communicates only with an asynchronous mobile communication network. Asynchronous preferred mode (WCDMA preferred), which performs mode switching for communication with a synchronous mobile communication network when it is out of the area of the mobile communication network, communicates with the synchronous mobile communication network first, and enters into an asynchronous mobile communication network, and communicates with the asynchronous mobile communication network. For this purpose, the communication mode may be set to any one of a synchronization preferred mode (CDMA preferred) for performing mode switching and a synchronization only mode (CDMA only) for communicating only with a synchronous mobile communication network.

4 is a conceptual diagram illustrating a mode switching method of a multi-mode multi-band mobile communication terminal according to the present invention.

The asynchronous mobile communication network 10 is located in the synchronous mobile communication network 20, and the multi-mode multi-band mobile communication terminal 400 in the boundary area 30 in which the asynchronous mobile communication network 10 and the synchronous mobile communication network 20 are overlaid. Is set to asynchronous priority mode to use asynchronous mobile communication service.

As shown, when the multi-mode multi-band mobile communication terminal 400 moves from the synchronous mobile communication network 20 to the asynchronous mobile communication network 10 to reach the boundary area 30, the base station of the synchronous mobile communication network 20 A mode change command including a parameter for this mode change is transmitted to the mobile communication terminal 400, and the mobile communication terminal 400 performs the switch from the synchronous mode to the asynchronous mode.

At this time, the asynchronous service unavailable area 40, which cannot be registered due to a problem in the asynchronous mobile communication network 10 or a weak electric field of the asynchronous mobile communication network 10 among the boundary areas 30 in which the mobile communication terminal 400 performs mode switching. ), The mobile communication terminal 400 switches to the synchronous mobile communication network 20 again, and the mobile communication terminal continues to be incapable of communication as the mobile communication terminal attempts to switch to the asynchronous mobile communication network again. Ping-Pong may occur. Here, location registration in the asynchronous mobile communication network 10 means location registration in the circuit network CS or location registration in the packet network PS.

Therefore, in the present invention, when the mobile communication terminal 400 enters the boundary area 30 and receives the synchronous-asynchronous mode switching command, the mobile communication terminal 400 switches to the asynchronous mode to search for an asynchronous signal and attempts location registration. If the 400 is in the asynchronous service unavailable area 40 having a problem in mode switching, after returning to the synchronous mode again, the mobile terminal 400 checks whether the mobile terminal 400 moves within the asynchronous mobile communication network 10, and is set in advance. If it moves more than the standard number, it initializes asynchronous signal search cycle.

If the user's movement is less than the preset reference number, the asynchronous signal search period is increased and the timer is driven.When the asynchronous signal search period is reached, that is, the asynchronous mode switching is performed again. Search for a signal.

Meanwhile, when the mobile communication terminal moves to the synchronous mobile communication network 20, it can be seen that the mobile communication terminal reenters the synchronous mobile communication network 20 from the changed base ID. Will operate in mode.

The movement of the mobile communication terminal 400 can be recognized using various methods. In the present invention, a method of recognizing the movement of the mobile communication terminal is confirmed by confirming that a base station providing a service is changed using a PN offset. It was.

In the synchronous mobile communication system, each synchronous base station transmits its assigned PN code to the mobile communication terminal 400 according to the PN offset, and the mobile communication terminal 400 generates the PN code using the PN offset. It is connected to the base station through this. That is, the change in the PN offset received by the mobile communication terminal 400 means that the mobile communication terminal 400 has moved.

Therefore, in the present invention, when the PN offset is changed more than a preset number of times, it is possible that the mobile communication terminal 400 has moved to an asynchronous network mobile communication network capable of location registration in an asynchronous service unavailable area where the ping pong phenomenon cannot occur due to the location registration. It judges that there is, and initializes asynchronous signal search cycle to switch to asynchronous mode.

For example, when using three PN codes per base station, it is preferable to set the number of PN offset changes to about 5 to initialize the asynchronous signal search period.

In addition, in the present invention, the search period of the asynchronous signal becomes longer as the number of asynchronous signal searches increases. However, if the user attempts to connect to the asynchronous mobile network continuously by increasing the search period, the terminal capable of asynchronous and synchronous simultaneous operation is not affected. However, when simultaneous operation is not possible, paging loss is detected during the search. In the present invention, the search attempt is performed only as much as the maximum number of searches (N _max ) of the asynchronous signal, so as not to continuously search.

That is, when the PN offset change count is less than the reference count, the terminal re-determines whether the number of times of searching for the asynchronous signal is greater than or equal to the maximum search count, and if the PN offset change count is less than the reference count, then the synchronization mode is determined. Keep it and no longer retrieve asynchronous signals.

The above process will be described in more detail with reference to the flowchart of FIG. 5.

5 is a flowchart illustrating a mode switching process from a synchronous mode to an asynchronous mode of a multi-mode multi-band mobile communication terminal according to the present invention.

The mobile communication terminal 400 enters the boundary area 30 to switch the mode from the BTS 201 of the synchronous mobile communication network coexisting in the same cell with the wireless station of the asynchronous mobile communication network to the base station identifier (BASE ID). When receiving the synchronous-asynchronous mode switching command including the parameter (S501), the mobile communication terminal 400 switches the current communication mode from the synchronous mode to the asynchronous mode (S502) to search for an asynchronous signal and whether an asynchronous signal is detected. It is determined whether (S503).

When the asynchronous signal is detected, the mobile communication terminal 400 determines whether location registration to the asynchronous mobile communication network 10 is completed (S504), and when location registration is completed, communication is performed through the asynchronous mobile communication network 10. Will be performed. In this case, location registration in the asynchronous mobile communication network 10 means location registration in the circuit network CS or location registration in the packet network PS.

On the other hand, if the asynchronous signal is not detected in the step S503, or the problem is not registered in the asynchronous mobile communication network in step S504 is unable to perform the communication in the asynchronous mode, the mobile communication terminal 400 is again in the synchronous mode Switch to (S505).

Thereafter, the mobile communication terminal 400 measures the PN offset transmitted from the base station (S506) and checks whether the PN offset is changed by the movement of the mobile communication terminal 400 (S507), and if the PN offset is changed, increases the number of changes. In step S508, the PN offset change count is compared with a preset reference count M (S509).

When the PN offset change count is more than the preset number M, the terminal 400 initializes the asynchronous signal search period and the PN offset change count (S510), returns to step S502, and switches to the asynchronous mode and the asynchronous signal. The search process is repeated until communication is possible in asynchronous mode.

In addition, when the PN offset change count is smaller than the preset number M in step S509, the terminal 400 determines whether the asynchronous signal search count n is greater than or equal to the asynchronous signal maximum search count N _max (S511). If the asynchronous signal search count (n) is greater than or equal to the asynchronous signal maximum search count (N _max ), the synchronous mode is maintained (S512) and the asynchronous signal search process is terminated.

If the asynchronous signal search frequency n is smaller than the asynchronous signal search frequency N _max in step S511, the terminal 400 calculates an asynchronous signal search period according to the asynchronous signal search frequency n, and sets a timer. It drives to count time (S513), and determines whether time has reached the calculated asynchronous signal search period (S514).

At this time, when the time reaches the asynchronous signal search period, the process returns to step S502 and switches back to asynchronous mode (S502) and searches for an asynchronous signal (S503) and repeats the above process until communication is possible in the asynchronous mode. If the asynchronous signal search period has not elapsed, the process returns to step S506 again to measure the PN offset, checks whether the PN offset is changed by the movement of the mobile communication terminal 400, and increases the asynchronous signal search period to determine the time. The process of determining whether the cycle is reached by counting is repeatedly performed.

The number of PN offset changes is increased until the user changes the mode to an asynchronous mobile communication network that can be initialized or communicates over a preset value or moves to a synchronous mobile communication dedicated network. In addition, the asynchronous signal search period is gradually increased according to a predetermined criterion according to the number of searches of the asynchronous signal, the counting time, that is, the parameter value for determining the asynchronous signal search period is included in the system parameters to the radio station of the asynchronous mobile communication network 10 Is transmitted from the mobile communication terminal 400 to.

Therefore, when the mobile communication terminal 400 receives a mode switching command in the asynchronous service unavailable area 40, the mobile communication terminal 400 returns to the synchronous mode and the mobile communication terminal 400 returns to the asynchronous mobile communication network 10. ) Check the PN offset value to see if it is moving within), and if the PN offset change count is more than the preset number, initialize the asynchronous signal search cycle. In addition, when the number of PN offset changes is less than the preset number, the asynchronous signal search period is increased by using the parameter value and the timer is driven. After the asynchronous signal search cycle is reached, asynchronous mode switching is performed to search for asynchronous signals.

On the other hand, the mobile communication terminal 400 is preferably set and stored in place of the default parameter value that can substitute for the parameter value, the mobile communication terminal 400 when the parameter value is not received from the system The asynchronous signal search period (t) is determined using the preset and stored basic parameter values.

In an embodiment, the parameter value may include unit interval information (T) for searching for an asynchronous signal, parameter information (A) for determining an asynchronous signal search period (t), and asynchronous signal maximum search frequency information (N _max). It may be configured to include).

When the number of times the mobile communication terminal 400 searches for an asynchronous signal is n, the mobile communication terminal 400 determines the asynchronous signal search period t according to the following equation as an example. .

t = A ⁿ * T

In the above formula, the asynchronous signal search frequency 'n' value has a value between '1' and 'N _max ' sequentially. That is, the initial asynchronous signal search cycle until the mobile communication terminal 400 does not register the location after receiving the mode change command and searches for the asynchronous signal again is 'A * T' after the time elapses. Otherwise, the asynchronous signal search period is 'A ² * T' and then the asynchronous signal search period is 'A ³ * T'.

As the above search process is repeated, when the number of asynchronous signal search times is equal to or greater than the value of 'N _max ', the terminal 400 no longer repeats the asynchronous signal search process and maintains the synchronous mode, thereby repeatedly unnecessary. Do not search for asynchronous signals.

The parameter value and equation for determining the asynchronous signal search period may be variously changed, and the 'n' value may have a value between '0' and 'N _max '.

At this time, the process of determining the asynchronous signal search period is made in the asynchronous service unavailable area 40 where the location registration is impossible because the electric field of the asynchronous mobile communication network 10 is weak, and the PN offset is changed by the movement of the mobile communication terminal 400. When the number of change PN offset changes to a predetermined number M or more, the asynchronous signal search period is initialized.

On the other hand, the present invention is applied only when the communication mode setting state of the multi-mode multi-band mobile communication terminal 400 is an asynchronous priority mode or a synchronous priority mode, and does not apply to the asynchronous dedicated mode or the synchronous dedicated mode.

Accordingly, when the mobile communication terminal 400 receives a mode switching command from the synchronous mobile communication network, the mobile communication terminal 400 determines the current communication mode setting state, and if the result of the determination is one of the asynchronous priority mode and the synchronous priority mode, the mobile communication terminal 400 searches for an asynchronous signal. It is preferable.

Meanwhile, in the above embodiment of the present invention, after switching to the synchronous mode, the PN offset measurement is performed first, and when the reference number is less than the reference number, it is determined whether the number of asynchronous signal searches is greater than or equal to the maximum number. After comparing the first, if the maximum number of times is not reached, it is natural that the PN offset measurement process may be performed.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

As described above, the synchronous-asynchronous mode switching method of the multi-mode multi-band mobile communication terminal of the present invention minimizes the ping-pong phenomenon and the paging loss caused by the frequent mode switching when the mobile communication terminal switches the mode between the synchronous and asynchronous. In addition, it is possible to prevent waste of radio resources and power consumption of mobile communication terminals due to frequent location registration, and to initialize asynchronous signal search cycle by using PN offset change frequency. Prevents asynchronous mode switching from slowing down due to an increase in the asynchronous signal retrieval period when moving, and limits the number of repetition of retrieval of the asynchronous signal to a predetermined maximum number of times, and stays in the synchronous mobile communication network for better wireless call quality. Can be provided.

Claims (9)

In the synchronous-asynchronous mode switching method of a multimode multiband mobile communication terminal comprising a synchronous modem unit for communication with a synchronous mobile communication network, an asynchronous modem unit for communication with an asynchronous mobile communication network, The mobile communication terminal is a system of an asynchronous mobile communication network for asynchronous signal search including a reference base station change number (M) for determining whether the terminal is moved and asynchronous signal search limit (N _max ) for limiting asynchronous signal search. Take a parameter value, A first step of retrieving an asynchronous signal by switching to an asynchronous mode when receiving the synchronous-asynchronous mode switching command from a synchronous mobile communication network in a boundary area where the areas of the asynchronous mobile communication network and the synchronous mobile communication network are overlaid; Determining a result of the asynchronous signal search, whether to search for an asynchronous signal, and whether to register a location in an asynchronous mobile communication network; A third step of switching the communication mode of the mobile communication terminal to the synchronous mode when the asynchronous signal is not found or the location registration to the asynchronous mobile communication network is not performed; Determining whether an access base station has changed due to the movement of the mobile communication terminal, and updating the base station change frequency according to the result, and then comparing the base station change frequency with the reference base station change frequency (M); If the base station change frequency is more than the reference base station change frequency (M), the asynchronous signal search period is initialized and fed back to the first step, and if the base station change frequency is smaller than the reference base station change frequency (M), the asynchronous signal search frequency ( a fifth step of determining whether n) is equal to or greater than the maximum number of asynchronous search times N _max ; If the asynchronous signal search frequency (n) is greater than or equal to the asynchronous signal maximum search frequency (N _max ), the asynchronous signal search process is terminated by maintaining the synchronous mode, and the asynchronous signal search frequency (n) is the asynchronous signal maximum search frequency (N _max ). Determining the asynchronous signal search period according to the number of asynchronous signal search times n, and driving a timer if smaller; A seventh step of returning to the first step when the timer passes the asynchronous signal search period; Method of switching between the synchronous and asynchronous mode of the multi-mode multi-band mobile communication terminal, characterized in that comprises a. The method of claim 1, The first step, Multi-mode-multiband movement, wherein the base station of the synchronous mobile communication network located in the boundary area where the areas of the asynchronous mobile communication network and the synchronous mobile communication network are overlaid is sent by commanding mode switching by sending a mode switching parameter. A method of switching between synchronous and asynchronous modes of a communication terminal. The method of claim 1, The first step, Determining, by the mobile communication terminal, a current communication mode setting state; And determining that the asynchronous signal is detected when the communication mode setting state is one of an asynchronous priority mode and a synchronous priority mode. The method of claim 1, The fourth step, Determining whether the PN offset is changed by measuring the PN offset transmitted from the base station, updating the PN offset change count according to the result, and then comparing the PN offset change count with the reference count (M). A method of switching between synchronous and asynchronous modes of a multimode multiband mobile communication terminal. The method of claim 1, In the sixth step, The asynchronous signal search period is gradually longer depending on the number of times of asynchronous signal search method of the synchronous-asynchronous mode switching of the multi-mode multi-band mobile communication terminal. The method of claim 1, In the sixth step, The asynchronous signal search period, And a method of switching between synchronous and asynchronous modes of the multi-mode multi-band mobile communication terminal. The method of claim 6, The system parameter value is Wherein the mobile communication terminal is one of a system parameter value received from an asynchronous mobile communication network and a system parameter value previously set and stored in the mobile communication terminal. How to switch between modes. The method of claim 6, The system parameter value further includes unit interval information (T) for searching for an asynchronous signal and parameter information (A) for determining an asynchronous signal search interval, When the number of asynchronous signal searches is n, the asynchronous signal search period is determined by Equation A ⁿ * T, and the asynchronous signal is searched until the value n of the asynchronous signal search count becomes the asynchronous signal maximum search count (N _max ). A method of switching between asynchronous and asynchronous modes of a multimode-multiband mobile communication terminal, characterized in that a period of asynchronous signal search is gradually increased as the number of searches increases. The method of claim 1, The seventh step, If the timer does not pass an asynchronous signal search period, returning to the fourth step; Method of switching between the synchronous and asynchronous mode of the multi-mode multi-band mobile communication terminal, characterized in that further comprising.

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