KR20060126036A - Idle handover method for dual band/dual mode mobile communication terminal - Google Patents

Abstract

An idle handover method for a dual band/dual mode mobile communication terminal is provided to quickly search an asynchronous signal when the dual band/dual mode mobile communication terminal is moved to an external area of a structure where the asynchronous signal is good through the number recognition of a satellite by a GPS(Global Positioning System) function embodied in a synchronous modem in a dead area of an overlay network, thereby increasing conversion speed into an asynchronous mode and reducing unnecessary asynchronous signal search frequency. An idle handover method for a dual band/dual mode mobile communication terminal comprises the following steps of: searching an asynchronous signal according to a decided signal search interval at an asynchronous signal search time(S150); determining whether recpetion power of the asynchronous signal is more than a threshold value if the asynchronous signal is searched, and in case of less than the threshold value, maintaining a synchronous mode, and in case of more than the threshold value, attempting location registration in an asynchronous network(S160,S110,S170); and maintaining the synchronous mode if the location registration to the asynchronous network is failed and converting into an asynchronous idle mode if the location registration is successful(S110,S180).

Description

Idle Handover Method for Dual Band / Dual Mode Mobile Communication Terminal}

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 applied to the present invention;

3 is a block diagram illustrating a configuration of a common module of FIG. 2;

4 is a flowchart illustrating a handover process from a synchronous mobile communication network to an asynchronous mobile communication network according to an embodiment of the present invention;

FIG. 5 is a flowchart illustrating an interval setting process according to an embodiment of the satellite search as the asynchronous signal search interval setting process of FIG. 4; FIG.

6 is a flowchart illustrating a process of setting an interval according to an embodiment of the asynchronous signal search interval setting procedure of FIG.

<Brief description of the main parts of the drawings>

100: asynchronous mobile network 200: synchronous mobile network

400: mobile communication terminal 410: antenna

420: asynchronous radio 430: synchronous radio

440: common module

The present invention relates to an idle handover method of a dual band / dual mode mobile communication terminal, wherein when a terminal in a synchronous mode searches for an asynchronous signal in an overlay area of an asynchronous network and a synchronous network without an asynchronous signal, Dual band / dual mode to determine whether it is outside the building using satellite signals and to increase the speed of switching to asynchronous mode by initializing the asynchronous signal search cycle when it is outside the building so that the asynchronous signal can be searched quickly. The present invention relates to an idle handover method of a mobile communication terminal.

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

Synchronous IMT-2000 service (synchronous mobile communication network) is evolving into CDMA2000 1x, CDMA2000 1x EV-DO, and asynchronous IMT-2000 service (asynchronous mobile communication network) is developing into WCDMA UMTS service. have. In such an environment, the problem of roaming between synchronous and asynchronous is the biggest problem. Accordingly, a terminal supporting dual band / dual mode has been developed to roam a synchronous mobile network and an asynchronous mobile network smoothly.

On the other hand, the asynchronous mobile communication network is built around an area with a high demand for services. Accordingly, the synchronous mobile communication network has a form in which the service area includes a service area of an asynchronous system. In the case of mutual movement between synchronous mobile communication systems, idle handover between systems is required for continuous service provision. Accordingly, various idle handover schemes have been proposed.

Currently, in a region where the base station ID is set to a value indicating that the base station ID is an asynchronous-synchronous overlay region, the terminal performs handover to the asynchronous mobile communication network again based on the base ID in order to maximize use of the asynchronous service. have. However, if the acquisition of the asynchronous signal or location registration into the asynchronous network fails, the terminal returns to the synchronous mode, increasing the interval between attempts to search the asynchronous network. The reason why the search interval is increased is that searching for the asynchronous signal at frequent intervals in the synchronous mode increases the current consumption of the asynchronous modem, thereby reducing the terminal waiting time.

The asynchronous signal search interval is set, for example, A ⁿ * T, where A and T are parameters for adjusting the asynchronous signal search interval, and n is the number of attempts to search for asynchronous signals and satisfies 0≤n≤Nmax. Is an integer, incremented by one. Therefore, if the UE fails to acquire and register an asynchronous signal, the search interval gradually increases exponentially until it reaches a maximum value, and when the terminal stays in the overlay region, which is an asynchronous shadow area, the network search interval increases so much that the asynchronous signal is good Even after returning to, there is a case where the asynchronous signal cannot be detected for a considerable period of time.

That is, according to the conventional handover method for preventing the ping-pong phenomenon in the overlay area where there is no asynchronous signal, the dual band / dual mode mobile communication terminal is moved from the asynchronous signal shadow area to the good asynchronous signal area by gradually increasing the asynchronous signal search interval. Even when entering, there is a problem that it takes a long time to acquire an asynchronous network.

Accordingly, the present invention is to solve the above disadvantages and problems of the prior art, when the terminal connected to the synchronous mobile communication network in the overlay area without asynchronous signal is moved to a good asynchronous signal, the asynchronous mobile communication network SUMMARY OF THE INVENTION An object of the present invention is to provide an idle handover method of a dual band / dual mode mobile communication terminal that enables an idle handover of a user to be performed quickly.

According to an aspect of the present invention, an asynchronous wireless device for performing asynchronous communication with the asynchronous mobile communication network, a synchronous communication with the synchronous mobile communication network, and a reception of a GPS satellite signal are carried out in a mobile communication network in which an asynchronous mobile communication network and a synchronous mobile communication network are mixed. IDLE handover of a dual band dual mode mobile communication terminal having a synchronous radio for performing and a common module for performing control during radio communication with the synchronous / asynchronous mobile communication network through the synchronous and asynchronous radios. A mobile communication terminal in a synchronous idle mode, which is present in an idle state in a synchronous mobile communication network via the synchronous radio, grasps a system parameter (Base ID) of a synchronous mobile communication network, and the current area is a synchronous mobile communication network. Determining whether or not the asynchronous mobile communication network is a mixed overlay area; As a result of the determination, in the overlay area, the signal search interval is calculated according to a predetermined rule such that the signal search interval increases as the number of asynchronous signal search attempts (n) after entering the synchronous mode increases. If a satellite signal is acquired from a synchronous modem without starting up and the number of satellites acquired is above a certain threshold, the asynchronous signal search interval is determined by initializing the number of asynchronous signal search attempts (n), and then the asynchronous signal search interval is determined. A second step of determining a signal search interval after increasing the number of asynchronous signal search attempts n when the number of times is less than a predetermined reference value; A third step of searching for an asynchronous signal when the asynchronous signal search point is reached according to the interval determined in the second step; A fourth step of, if the asynchronous signal is found, determining whether the received power of the asynchronous signal is greater than or equal to a threshold value, maintaining a synchronous mode if less than the threshold value, and attempting to register a position in the asynchronous network if it is greater than or equal to the threshold value; A fifth step of maintaining a synchronous mode if the location registration fails in the asynchronous network and switching to the asynchronous idle mode if the location registration is successful; It is achieved by the idle handover method of the dual-band / dual mode mobile communication terminal comprising a.

In addition, the object of the present invention is a mobile communication network in which an asynchronous mobile communication network and a synchronous mobile communication network is mixed, an asynchronous wireless device for performing asynchronous communication with the asynchronous mobile communication network, synchronous communication with the synchronous mobile communication network and GPS satellite signals Synchronous wireless device for performing the reception, and a common module for performing the control during the wireless communication with the synchronous / asynchronous mobile communication network through the synchronous and asynchronous wireless device, overlay the mixed synchronous mobile network and asynchronous mobile communication network After entering the synchronous mode in the region, the dual search for the asynchronous signal by calculating the signal search interval according to a certain rule that the signal search interval increases as the number of asynchronous signal search attempts (n) increases for handover to the asynchronous mode. Idle handover method of band dual mode mobile communication terminal The mobile terminal of the synchronous idle mode, which is present in the idle state through the synchronous wireless device, identifies the system parameter (Base ID) of the synchronous mobile communication network, and the current area is moved asynchronously with the synchronous mobile communication network. Determining whether the communication network is a mixed overlay area; As a result of the determination, in the overlay area, satellite signals are acquired by the synchronous modem without periodically starting the asynchronous modem, and when the number of acquired satellites is equal to or greater than a predetermined reference value, regardless of the signal search interval that increases with the number of search attempts (n). Retrieving an asynchronous signal; Determining if the received power of the asynchronous signal is greater than or equal to a threshold value, maintaining a synchronous mode if less than the threshold value, and attempting to register a location in the asynchronous network if the asynchronous signal is greater than or equal to the threshold value; A fourth step of maintaining a synchronous mode if the location registration to the asynchronous network fails, and switching to the asynchronous idle mode if the location registration is successful; It is achieved by the idle handover method of the dual-band / dual mode mobile communication terminal comprising a.

Detailed description of the above object and technical configuration of the present invention and the effects thereof according to the present invention will be more clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

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

As shown in FIG. 1, an asynchronous mobile communication network (WCDMA network) 100 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 '102 and 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 an asynchronous communication network data service gateway node (hereinafter referred to as 'GGSN') 106 which is a relay device for performing the packet service control and packet data transmission through the GPRS network 105.

In addition, an exchanger (hereinafter referred to as 'MSC') 104 is connected to the RNC 102 to perform a call exchange, and the MSC 104 is a number seven signal network (No. 7 signal network) for signal exchange ( 107). The number seven signal network 107 has a short message service center (hereinafter referred to as 'SMSC') 108 that services a short message, an intelligent network controller (hereinafter referred to as 'SCP') 109, and subscriber location information. Home location register (hereinafter referred to as 'HLR') for managing the 110 is connected.

On the other hand, the synchronous mobile communication network (CDMA2000 network) 200, the base station for performing wireless communication with the mobile communication terminal 400 (hereinafter referred to as 'BTS') 201 and the base station for controlling the BTS 201 A controller (hereinafter referred to as '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 A data core network (hereinafter referred to as "DCN") 209 connected to 204 and performing an Internet access service, and a switch connected to the BSC 202 to perform an exchange (hereinafter referred to as "MSC") 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, an intelligent network controller (hereinafter referred to as an 'SCP') 207 for serving a short message, and subscriber's location information. A home location register (hereinafter referred to as 'HLR') 208 for managing the connection is connected.

The MSCs 104 and 203 of the asynchronous mobile communication network 100 and the synchronous mobile communication network 200 are interconnected, and the number seven signal networks 107 and 205 are also interconnected to handover the mobile communication terminal 400. Information necessary for transmitting and receiving is transmitted.

In addition, in this embodiment, the synchronous mobile communication network 200 and the asynchronous mobile communication network 100 have HLRs 110 and 208 for managing subscriber information and location information, respectively, but one HLR (dual stack home location). The synchronous mobile communication network 200 and the asynchronous mobile communication network 100 may share subscriber information and location information by using a register.

The asynchronous mobile communication network 100 includes UMTS, GSM, GPRS, EDGE, and the like, and the synchronous mobile communication network 200 includes 2G, 1X, EV-DO, EV-DV, and the like.

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

As shown, the dual-band mobile communication terminal 400 is to support both synchronous and asynchronous mobile communication has a stack of each protocol.

The mobile communication terminal 400 according to the present invention is broadly divided into an antenna 410 for transmitting and receiving radio signals and a satellite signal transmission and reception with the synchronous mobile communication network 200 and the asynchronous mobile communication network 100, and synchronous radio for synchronous communication. Device 430, asynchronous radio 420 for asynchronous communication, and 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, in the present invention, the synchronous radio 430 should further include a GPS RF module 435 and a GPS processor 436, and the GPS RF module 435 may be built in or external to the synchronous radio transmitter 432. The GPS processor 436 may be configured in the synchronous modem unit 434 or may be configured as a separate chip externally.

The asynchronous radio apparatus 420 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.

The common module 440 includes an application processor, a memory, an input / output unit, other application processing units, etc. that operate as a central processing unit for controlling the synchronous modem unit 434 and the asynchronous modem unit 424 and perform multimedia functions. Detailed configuration is as follows.

3 is a block diagram illustrating a configuration of a common module of FIG. 2.

As shown, the common module 440 of the mobile communication terminal according to the present invention includes a plurality of dual ports connected to the modem units 424 and 434 of the synchronous radio 430 and the asynchronous radio 420. RAM (Dual Port RAM, hereinafter referred to as 'DPRAM') 441 and 442, connected to the DPRAM 441 and 442, and performs 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.

The common module 440 having the above-described configuration is equipped with software for user interface, additional service, mobility management, access / session control, resource control, and protocol processing, so that users can use various application services and handover. Performs protocol conversion according to the mobile communication system.

4 is a flowchart illustrating a handover process from a synchronous mobile communication network to an asynchronous mobile communication network according to an embodiment of the present invention, in which a mobile communication terminal operating in a synchronous mode operates in an asynchronous mode. It shows the handover process.

Here, the synchronous mode means a mode capable of transmitting and receiving user traffic through the synchronous network, and the asynchronous mode means a mode capable of transmitting and receiving user traffic through the asynchronous network.

Therefore, when a dual mode / dual band mobile communication terminal is capable of transmitting and receiving user traffic through a synchronous modem, a process of turning on the asynchronous modem to request registration and receiving a response to the asynchronous network is also included in the synchronous mode. Turning off the synchronous modem (or switching the synchronous modem to a low power mode) and allowing user traffic to be sent and received through an asynchronous modem is called asynchronous mode. Similarly, when a user can send and receive user traffic through an asynchronous modem, asynchronous mode includes requesting registration or receiving a response from the synchronous modem.

As shown, if the dual band / dual mode terminal operating in the synchronous mode (S110) recognizes that the overlay area (S120), the terminal performs a process of setting the asynchronous signal search interval (S130).

In this case, it is recognized that the overlay area includes whether the value of the second bit indicating whether the asynchronous network is mixed with the base ID, which is a system parameter value of the synchronous network in which the asynchronous network and the synchronous network are mixed, is set to "1". By determining whether or not. That is, if the second bit of the base ID is "1", the terminal recognizes that it is an overlay area (S120) and performs an asynchronous signal search interval setting process (S130), otherwise maintains a synchronous mode (S110).

The asynchronous signal search interval setting process is a process of determining a search point for searching for an asynchronous signal, and calculates the time until the search time so that the asynchronous signal can be searched after the elapsed time, which is illustrated in FIGS. 5 and 6. It will be described in detail through.

Next, the terminal counts the amount of time determined by the step S130 (S140), when it is time to search for the asynchronous signal, the asynchronous modem switches from the low power mode to the idle (IDLE) mode to retrieve the asynchronous signal (S150), The strength of the asynchronous signal is measured to determine whether the asynchronous signal reception power RSCP is greater than or equal to the threshold TH (S160).

If the strength of the asynchronous signal is less than the threshold value, the terminal maintains the synchronous mode (S110). If the threshold value is greater than the threshold value, the terminal attempts to register the position in the asynchronous mobile communication network (S170).

At this time, if the location registration to the asynchronous mobile communication network is successful, the terminal switches to the asynchronous mode (S180), if registration fails, maintains the synchronous mode (S110).

On the other hand, if the received power of the asynchronous signal is less than the threshold value in step S160, or fails to register the location to the asynchronous network in S170 the terminal maintains the synchronous mode. That is, since the terminal stays in the overlay area and operates in the synchronous mode and searches for the asynchronous signal repeatedly, the current consumption in the asynchronous modem increases due to frequent asynchronous signal searches. If the asynchronous signal search is repeated, the asynchronous signal search interval is gradually increased through the asynchronous signal search interval setting process (S130).

Further, in the present invention, while the terminal stays in the overlay area and operates in a synchronous mode, the terminal searches for an asynchronous signal by gradually increasing the asynchronous signal search interval according to the search interval setting process (S130), but periodically or when a predetermined condition is a GPS RF module. Search for satellite signals through (435), and if the number of satellites detected is greater than a certain number (e.g., 3), it is determined to be out of the building, and the search interval is shortened to search for asynchronous signals quickly. Increase the interval or skip the search.

The search interval setting process (S130) according to the present invention will be described in detail with reference to FIGS. 5 and 6.

FIG. 5 is a flowchart illustrating an interval setting process according to an embodiment of the satellite search as the asynchronous signal search interval setting process of FIG. 4, wherein a dual mode / dual band terminal operating in a synchronous mode searches for an asynchronous signal in an overlay region. FIG. It shows the process according to satellite signal search among the set algorithms.

In the present invention, the asynchronous signal search interval is increased as the number of asynchronous signal search intervals is increased, and in FIG. 5, the case where the asynchronous signal search interval is determined as A ⁿ * T will be described as an example. Here, A and T are parameters for adjusting the asynchronous signal search interval, n is an integer that satisfies the condition of 0≤n≤Nmax as the number of asynchronous signal search attempts, and increases by 1 according to the repeated search of the asynchronous signal.

As shown, while the terminal in the overlay area of the current asynchronous network and the synchronous network is repeatedly searching for the asynchronous signal while gradually increasing the asynchronous signal search interval in the synchronous mode, the number of asynchronous signal search times (n) exceeds a certain number of times. When the search period is long (S131), GPS satellite signals are acquired periodically using the GPS RF module 435 and the GPS processor 436 implemented in the synchronous radio 430 (S132).

In the present invention, the acquisition of the satellite signal is determined whether the terminal in the synchronous mode is repeatedly searching for an asynchronous signal, whether it is currently inside the building or outside the building and adjust the search interval or adjust the asynchronous signal search interval accordingly. If the number of acquired satellites is above a certain threshold, the process of searching for asynchronous signals may be newly inserted between the original asynchronous signal search intervals. The periodic acquisition of the satellite signal can be performed after the number of asynchronous signal repetition retrieval times n is increased to a certain number, as in the above embodiment, to increase the search interval to some extent, and immediately after the repetitive retrieval of the asynchronous signal is started. It may be performed by driving a timer for determining a satellite signal search time. That is, step S131 can be omitted.

Next, when the GPS satellite signal is obtained, the terminal determines whether the number of GPS satellites that transmit the satellite signal is more than a predetermined reference value (for example, three) that can be determined whether or not inside and outside the building (S133), and if it is above the reference value It is determined to be outside the building to initialize the asynchronous signal repetition search count (n) for fast signal search (S134) and sets the search interval (S136). In this case, the search interval is set by increasing the number of times of asynchronous signal repetition search n once (S135).

In the drawing, the number of searches is increased when it is determined to be in a building, and the number of searches is initialized when it is determined to be outside a building. In parallel with the setting process, you can insert the asynchronous signal search process by searching for asynchronous signals immediately outside the building without adjusting the number of searches, and adjust the search interval by omitting one asynchronous signal search within the building. It may be.

In addition, the search interval may be gradually increased in the building without using a separate asynchronous signal search interval setting algorithm, and the search interval may be fixed in the outside of the building to search for the asynchronous signal.

In addition, there may be various embodiments of a method for searching for a satellite signal. For example, when the terminal is in the sleep mode, the terminal does not search for the satellite signal and only when the terminal is in the wakeup mode. Searching for satellite signals can reduce current consumption. That is, the terminal may search for satellite signals according to the slot period for searching the call channel.

Meanwhile, as described above, the search interval setting according to the satellite search may be based on the search interval gradually increasing as the number of asynchronous signal repetition searches (n) increases. An embodiment of the process will be described with reference to FIG. 6 as follows.

6 is a flowchart illustrating a process of setting an interval according to an embodiment of the asynchronous signal search interval setting procedure of FIG.

As shown in the drawing, it is determined whether the first asynchronous signal search is attempted in the synchronous mode (S131-1), and if the first attempt is performed, the terminal initializes n, which is a value indicating the number of asynchronous signal search times, to 0 ( S132-1).

Next, the terminal checks the base ID of the synchronization network (S133-1), if the base ID has not changed by increasing the value of n (S134-1) by calculating the search interval by applying the increased n value (S135-1) ) Increase the search period.

The asynchronous signal retrieval period is gradually increased according to a predetermined criterion according to the number of retrieval of the asynchronous signal, and a parameter value for determining a counting time (asynchronous signal retrieval period) is included in a system parameter so that a mobile station can be received from a mobile station of an asynchronous mobile communication network. Is sent to. In addition, the terminal may be configured to store and store the default parameter value that can be substituted for the parameter value so that the asynchronous signal search period may be determined using the preset and stored default parameter value when the parameter value is not received from the system. It is desirable to.

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, and asynchronous signal maximum search count information (Nmax). When the number of times the mobile communication terminal attempts to search for an asynchronous signal is 'n', the terminal determines the asynchronous signal search period according to the following equation.

t = A ⁿ * T

In the above equation, the 'n' value, which is the number of asynchronous signal searches, has a value between '0' and 'Nmax' sequentially. In other words, after recognizing that the mobile communication terminal is an overlay area, the search period is 'A ⁰ * T' when the first asynchronous signal is searched. 'A ¹ * T', when retrieving the signal after the location registration is not performed even after the time elapses, the asynchronous signal search period is 'A ² * T', and the next asynchronous signal search period is 'A ³ * T' To be.

As the above search process is repeated, if the number of asynchronous signal search times is equal to or greater than 'Nmax', the asynchronous signal search period is fixed to 'A ^Nmax * T' or reinitialized regardless of the number of subsequent asynchronous signal searches. can do.

Parameter values and equations for determining the asynchronous signal search period may be variously changed.

On the other hand, when the determination result of step S131-1 is not the first attempt, the terminal determines whether registration to the asynchronous network has failed in retrieving the previous asynchronous signal (S132-2), and fails to register the previous asynchronous network. If so, the terminal increases the search value by increasing the value of n (S134-1) (S135-1). That is, when the terminal acquires an asynchronous signal above a certain threshold but fails to acquire the asynchronous signal but fails to register, the terminal does not initialize the n value and adds 1 to the previously used n value to increase the n value. (S134-1).

Here, the terminal does not perform the step (S133-1) of determining whether the base ID is changed (not to reduce the search period even if the base ID is changed) succeeded in asynchronous signal acquisition but the system is unstable in a specific test network If you do so, you may have refused to register. Therefore, the reason for registration failure is not the shaded area but the deliberate operation in the network. In this case, if the base ID is changed even though the registration is rejected, the search is performed at a rapid cycle, which increases the current consumption and network load. It is to perform step S134-1 of increasing the value of n without performing step S133-1 of determining whether the ID is changed.

On the other hand, if it is not the first attempt as a result of the determination in step S131-1, and if the registration of the asynchronous network is not failed in the previous step as a result of the determination in step S132-2, the terminal checks the base ID of the synchronization network. If the base ID is not changed (S133-1), the value n is increased (S134-1) to increase the search period (S135-1). This is to reduce the current consumption during asynchronous signal search by increasing the search period when the terminal stays in the shadowed area for a long time.

If the base ID is changed, the terminal initializes n to 0 (S134-2) and determines the search interval (S135-1) so that the asynchronous signal can be searched with a fast search period. That is, since the shaded area of most overlay areas is smaller than the base station area, it is considered that the change of the base station is out of the shadow area. If the base ID of the synchronous network is changed, the terminal assumes that the shadow area has been left and initializes n. To quickly retrieve asynchronous signals.

The asynchronous signal search interval setting process described with reference to FIG. 6 may be performed in parallel with the process of FIG. 5, or any one of the process of FIG. 5 and the process of FIG. 6 may be alternatively performed.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. 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.

Therefore, according to the idle handover method of the dual-band / dual mode mobile communication terminal of the present invention, the current required for GPS search in the synchronous modem is significantly smaller than that of starting the asynchronous modem to search for an asynchronous signal. The GPS can be searched at a much faster interval than the interval, and the GPS function implemented in the synchronous modem in the shaded area of the overlay network quickly detects the asynchronous signal when the asynchronous signal is moved to the outside area of the building through recognition of the number of satellites. By doing so, the speed of switching to the asynchronous mode is increased, and according to the exemplary embodiment, the number of unnecessary asynchronous signal searches is reduced.

Claims (5)

In a mobile communication network in which an asynchronous mobile communication network and a synchronous mobile communication network are mixed, an asynchronous radio for performing asynchronous communication with the asynchronous mobile communication network, and a synchronous radio for performing synchronous communication with the synchronous mobile communication network and GPS satellite signal reception. And an idle (IDLE) handover method of a dual band dual mode mobile communication terminal having a common module for performing control during wireless communication with the synchronous / asynchronous mobile communication network through the synchronous and asynchronous wireless devices. Through the synchronous radio, the synchronous idle mode mobile communication terminal present in the idle state in the synchronous mobile communication network grasps the system parameter (Base ID) of the synchronous mobile communication network, and the current area is the synchronous mobile communication network and the asynchronous mobile communication network. A first step of determining whether the mixed overlay area is present; As a result of the determination, in the overlay area, the signal search interval is calculated according to a predetermined rule such that the signal search interval increases as the number of asynchronous signal search attempts (n) after entering the synchronous mode increases. If a satellite signal is acquired from a synchronous modem without starting up and the number of satellites acquired is above a certain threshold, the asynchronous signal search interval is determined by initializing the number of asynchronous signal search attempts (n), and then the asynchronous signal search interval is determined. A second step of determining a signal search interval after increasing the number of asynchronous signal search attempts n when the number of times is less than a predetermined reference value; A third step of searching for an asynchronous signal when the asynchronous signal search point is reached according to the interval determined in the second step; A fourth step of, if the asynchronous signal is found, determining whether the received power of the asynchronous signal is greater than or equal to a threshold value, maintaining a synchronous mode if less than the threshold value, and attempting to register a position in the asynchronous network if it is greater than or equal to the threshold value; A fifth step of maintaining a synchronous mode if the location registration fails in the asynchronous network and switching to the asynchronous idle mode if the location registration is successful; Idle handover method of a dual band / dual mode mobile communication terminal, characterized in that comprises a. In a mobile communication network in which an asynchronous mobile communication network and a synchronous mobile communication network are mixed, an asynchronous radio for performing asynchronous communication with the asynchronous mobile communication network, and a synchronous radio for performing synchronous communication with the synchronous mobile communication network and GPS satellite signal reception. And a common module for performing control during wireless communication with the synchronous / asynchronous mobile communication network through the synchronous and asynchronous wireless devices, and after entering the synchronous mode in the overlay region where the synchronous mobile network and the asynchronous mobile communication network are mixed. Idle of dual-band dual-mode mobile communication terminal that searches for asynchronous signals by calculating the signal search interval according to a regular rule that increases the number of asynchronous signal search attempts (n) for handover to asynchronous mode. (IDLE) As a handover method, The mobile terminal in the synchronous idle mode, which is present in the idle state in the synchronous mobile communication network through the synchronous wireless device, grasps the system parameter (Base ID) of the synchronous mobile communication network, and the current area is moved asynchronously with the synchronous mobile communication network. Determining whether the communication network is a mixed overlay area; As a result of the determination, in the overlay area, satellite signals are acquired by the synchronous modem without periodically starting the asynchronous modem, and when the number of acquired satellites is equal to or greater than a predetermined reference value, regardless of the signal search interval that increases with the number of search attempts (n). Retrieving an asynchronous signal; Determining if the received power of the asynchronous signal is greater than or equal to a threshold value, maintaining a synchronous mode if less than the threshold value, and attempting to register a location in the asynchronous network if the asynchronous signal is greater than or equal to the threshold value; A fourth step of maintaining a synchronous mode if the location registration to the asynchronous network fails, and switching to the asynchronous idle mode if the location registration is successful; Idle handover method of a dual band / dual mode mobile communication terminal, characterized in that comprises a. The method according to claim 1 or 2, In the second step, The satellite signal acquisition cycle is an idle handover method of a dual band / dual mode mobile communication terminal, characterized in that it is a multiple of a wakeup cycle of the terminal. The method according to claim 1 or 2, In the second step, And the terminal starts acquiring a periodic satellite signal when the number of asynchronous signal search attempts n is greater than or equal to a predetermined number of times. The idle handover method of a dual band / dual mode mobile communication terminal. The method according to claim 1 or 2, The terminal is asynchronous by equation A ⁿ * T using unit interval information (T) for searching for asynchronous signals, parameter information (A) for determining an asynchronous signal search period, and the number of asynchronous signal search attempts (n). An idle handover method of a dual band / dual mode mobile communication terminal, characterized by calculating a signal search interval t.

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