KR100747749B1 - Multiband-multimode terminal and modem operation method for multiband-multimode terminal - Google Patents

Abstract

A mobile communication terminal and a modem driving method of an MB-MM(Multiband Multimode) mobile communication terminal are provided to limit the second modem so that the second modem is not driven in low-power mode if the MB-MM terminal performs wireless communication in the first mobile communication network only, thereby preventing unnecessary power consumption. If RRC(Radio Resource Control) connection for wireless communication is required, a master modem(210) detects signal strength information from radio station information(300,315). The master modem compares the extracted signal strength information with a preset threshold value(320). If the signal strength information is weaker than the threshold value, the master modem decides whether a slave modem(220) is driven in low-power mode(325). If not, the master modem outputs a low power driving command to the slave modem. The slave modem receives the command to start driving in the low-power mode(335).

Description

Modem driving method for mobile communication terminal and MMB-MM mobile communication terminal {Multiband-multimode terminal and modem operation method for multiband-multimode terminal}

1 is a diagram schematically illustrating a mobile communication network for providing a WCDMA service in a communication environment in which a CDMA mobile communication network is basically constructed.

2 is a block diagram of an MB-MM mobile communication terminal and a mobile communication network according to an embodiment of the present invention.

3 is a flowchart illustrating a modem driving method in an MB-MM mobile communication terminal according to an embodiment of the present invention.

4 is a flowchart illustrating a modem driving method in an MB-MM mobile communication terminal according to another preferred embodiment of the present invention.

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

100: existing CDMA mobile communication network

110-1, 110-2, 110-3: overlay area

120-1, 120-2, 200: MB-MM mobile communication terminal

210: master modem

220: slave modem

270: first mobile communication network

271: first network RNC

272: first network MSC

280: second mobile communication network

281: second network BSC

282: second network MSC

The present invention relates to a multi-band (MB) -MM (multimode) mobile communication terminal, and more particularly to a method for driving a modem of an MB-MM mobile communication terminal.

In general, a mobile communication terminal is a portable device capable of making a voice call with a counterpart located at a remote location while moving. Initially, only a voice communication was possible, but a mobile communication terminal has evolved into a data communication method using text and symbols and a multimedia communication method including a video signal.

The voice and text communication method has a relatively small data capacity, and therefore, a mobile communication system of a code division multiple access (CDMA) method is suitable. However, in the multimedia communication method including the recent video signal, a large amount of data requires a mobile communication system having a high data output speed. A system suitable for such a requirement is a third generation (3GPP) mobile communication system. For example, a wideband code division multiple access (WCDMA) type mobile communication system.

In addition, the mobile communication terminal may be variously classified according to the mobile communication network access method. That is, the portable terminal for voice and data communication by connecting to the CDMA mobile communication system, the portable terminal for multimedia communication by connecting to the WCDMA mobile communication system, and the MB which accepts and selectively connects and communicates with both the CDMA and WCDMA methods. -MM may be classified into a mobile communication terminal.

1 is a diagram schematically illustrating a mobile communication network for providing a WCDMA type service in a communication environment in which a CDMA mobile communication network is basically constructed.

As shown in FIG. 1, CDMA-type services are currently provided in a wide range of areas 100, but WCDMA-type services are provided in some regions 110-1, 110-2, 110-3, and CDMA-type service regions. Collectively referred to as '110'). Thus, some regions within the CDMA coverage area may overlap with the WCDMA coverage area, such an area may be referred to as an overlay area 110. Of course, the WCDMA service area may exist independently in an area other than the CDMA service area.

The overlay area 110 is a form in which a conventional CDMA mobile communication network, which is a second generation mobile communication network, and a WCDMA mobile communication network, which is a third generation mobile communication network, coexist. Accordingly, in order to be able to selectively use the WCDMA type service and the CDMA type service in the overlay area 110, the user has both a CDMA modem and a WCDMA modem, and MB-MM mobile communication selectively operates between the modems. Terminals 120-1, 120-2, hereafter referred to as '120' should be provided.

In addition, when a user moves between the WCDMA mobile communication network 110 and the CDMA mobile communication network 100 in the process of using the MB-MM mobile communication terminal 120, the modems of the respective modes of the terminal are provided to provide continuous services. Handover is required.

However, when the MB-MM mobile communication terminal 120 performs the handover from the WCDMA modem to the CDMA modem, the WCDMA modem receives a message requesting a handover from the WCDMA mobile communication network to operate the CDMA modem by several seconds or more. Time is required. Thus, there was a problem that the call is disconnected when the modem is handed over while performing wireless communication.

In order to solve this problem, the conventional MB-MM mobile communication terminal 120 transmits a signal from the WCDMA modem to the WCDMA mobile communication network 110 for smooth handover from the WCDMA mobile communication system to the CDMA mobile communication system. Alternatively, the CDMA modem was driven to a low power mode (LPM) once the incoming call was attempted. Here, the low power mode refers to a state in which the power of the CDMA modem is applied, but does not perform a communication function, and has a small current consumption compared to a conventional idle state in which current consumption is 1 mA to 1.5 mA. Then, when the WCDMA modem receives a message for requesting a handover from the WCDMA mobile communication network, the MB-MM mobile communication terminal 120 performs the handover from the WCDMA modem to the CDMA modem.

 When performing the wireless communication by the above-described method, the wireless connection can be prevented due to the driving time of the CDMA modem, but the MM-MB mobile communication terminal 120 performs wireless communication only in the WCDMA mobile communication network 110. In this case, the CDMA modem is operated in a low power mode. In this case, the driving means not a driving state for communication but a standby state because it means a state in which communication is prepared while consuming low power. That is, even when the handover is not performed, the CDMA modem is driven in a low power mode, which causes the MB-MM mobile terminal 120 to consume power unnecessarily.

Therefore, in the present invention, when the MB-MM mobile communication terminal including the first modem and the second modem performs wireless communication only in the first mobile communication network, the second modem is not driven in the low power mode. And to provide a modem driving method in the MB-MM mobile communication terminal.

In addition, the present invention, when the MB-MM mobile communication terminal 120 including the first modem and the second modem performs wireless communication in the first mobile communication network, unnecessary power generated by driving the second modem in a low power mode The present invention provides a method for driving a modem in an MB-MM mobile communication terminal and an MB-MM mobile communication terminal capable of preventing consumption.

Other objects of the present invention will be readily understood through the following description.

In order to achieve the above objects, there is provided an MB-MM mobile communication terminal according to an aspect of the present invention.

According to a preferred embodiment of the present invention, in the MB-MM mobile communication terminal comprising a first modem and a second modem each performing a wireless communication with a different mobile communication network, the first modem is received from the first mobile communication network An MB-MM mobile communication terminal is provided which controls the second modem to be driven in the low power mode only when the received signal strength information is smaller than a preset threshold.

The first modem may output a low power driving command to the second modem only when the second modem is not running in the low power mode.

The second modem in a driving termination state may start driving in a low power mode by the low power driving command input from the first modem.

When the received signal strength information is greater than or equal to the threshold value, the first modem may perform an RRC connection process to the first mobile communication network.

The received signal strength information may be received signal code power.

In order to achieve the above objects, there is provided an MB-MM mobile communication terminal according to another aspect of the present invention.

According to another preferred embodiment of the present invention, in a MB-MM mobile communication terminal including a first modem and a second modem each performing wireless communication with a different mobile communication network, the first modem is received from the first mobile communication network. When the received signal strength information is greater than or equal to a preset threshold, an MB-MM mobile communication terminal is provided so as to control the second modem to switch to a driving termination state.

The first modem may output a driving end command to the second modem only when the second modem is being driven in the low power mode.

The second modem driving in the low power mode may terminate driving by the driving termination command input from the first modem.

The received signal strength information may be received signal code power.

In order to achieve the above objects, there is provided a recording medium in which a modem driving method and / or a program for executing the method in an MB-MM mobile communication terminal according to another aspect of the present invention is recorded.

According to still another preferred embodiment of the present invention, in a method for driving a modem in an MB-MM mobile communication terminal including a first modem and a second modem each performing wireless communication with a different mobile communication network, the first modem may be Detecting received signal strength information from radio station information received from the first mobile communication network; Comparing, by the first modem, the received signal strength information with a preset threshold value; And when the received signal strength information is smaller than the threshold, the first modem outputting a low power driving command, wherein the second modem starts to be driven in a low power mode by the low power driving command. A modem driving method in an MB-MM mobile communication terminal is provided.

The first modem may further include determining whether the second modem is being driven in a low power mode when the received signal strength information is smaller than the threshold, wherein the first modem may be configured to be low power. The low power drive command may be output to the second modem only when the device is not driven in the mode.

The first modem may perform an RRC connection process to the first mobile communication network when the received signal strength information is greater than or equal to the preset threshold.

The received signal strength information may be received signal code power.

In order to achieve the above objects, there is provided a recording medium in which a modem driving method and / or a program for executing the method in an MB-MM mobile communication terminal according to another aspect of the present invention is recorded.

According to still another preferred embodiment of the present invention, in a method for driving a modem in an MB-MM mobile communication terminal including a first modem and a second modem each performing wireless communication with a different mobile communication network, the first modem may be Detecting received signal strength information from radio station information received from the first mobile communication network; Comparing, by the first modem, the received signal strength information with a preset threshold value; And outputting a drive termination command by the first modem only when the received signal strength information is greater than or equal to the threshold value, wherein the second modem which is being driven in a low power mode is terminated by the drive termination command. A modem driving method in an MB-MM mobile communication terminal is provided.

The first modem may further include determining whether the second modem is operating in a low power mode when the received signal strength information is greater than or equal to the threshold value, wherein the first modem may be configured to enter the low power mode. The driving end command may be output to the second modem only when the driving is in progress.

The received signal strength information may be received signal code power.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Ordinal numbers (eg, first and second) added to distinguish the same or similar components in the present specification are merely added in the order in which each component is described for each paragraph or description. It should be noted that this is not intended to specify the name of each component or to limit the scope of rights.

The following merely illustrates the principles of the invention. Therefore, those skilled in the art, although not explicitly described or shown herein, can embody the principles of the present invention and invent various methods and apparatus using the same that are included in the concept and scope of the present invention. In addition, it is to be understood that all detailed descriptions, including the principles, aspects, and embodiments of the present invention, as well as listing specific embodiments, are intended to include structural and functional equivalents.

In this specification, for convenience of description, the first modem is defined as a master modem and the second modem is defined as a slave modem for convenience, but the present invention is limited by the terms (ie, first, second, master, and slave). It is self-evident.

Hereinafter, in describing the communication structure between the MB-MM mobile communication terminal and the mobile communication network according to the present invention, the master modem provided in the MB-MM mobile communication terminal is a WCDMA modem, and the slave modem is a CDMA modem. It is assumed that it is. However, it is obvious that the modem included in the MB-MM mobile communication terminal is not limited to the CDMA modem and the WCDMA modem. Although a separate description is omitted, it is apparent that the MB-MM mobile communication terminal according to the present invention may include two or more slave modems.

In addition, it is assumed that the first mobile communication network connected to the master modem and performing communication is the WCDMA mobile communication network, and the second mobile communication network connected to the slave modem and performing communication is the CDMA mobile communication network. Here, the first mobile communication network and the second mobile communication network may be included in one mobile communication system. In addition, it is apparent to those skilled in the art that the present invention can be applied to the same or similar to other types of mobile communication methods (for example, TDMA, GSM, etc.).

2 is a block diagram of an MB-MM mobile communication terminal and a mobile communication network according to an embodiment of the present invention.

As shown in FIG. 2, the MB-MM mobile communication terminal 200 according to an exemplary embodiment of the present invention includes a master modem 210, a slave modem 220, a master high frequency processor 230, and a slave high frequency processor ( 240, a control path 250, a storage 255, a duplexer 260, and an antenna 265. In addition, it is obvious that the MB-MM mobile communication terminal 200 may further include a display unit, an input unit, and the like.

The master modem 210 processes various signals of base bands when the MB-MM mobile communication terminal 200 operates in a master mode (that is, a communication mode using a communication method according to the master modem 210). And control. In particular, when power is applied while the MB-MM mobile communication terminal 200 is located in the service area of the first mobile communication network 270 (Power on), an initial searching is performed to perform a first mobile communication network 270. ) Is driven to an idle state. An idle state refers to a state in which a terminal waits for a call and / or data transmission without performing an operation such as call and / or data transmission.

In addition, when there is a need for a Radio Resource Control (RRC) connection (for example, a telephone call), the radio station information received from the first mobile communication network 270 in an idle state (for example, Received signal strength information (e.g., received signal code power) is detected from the system information blocks SIB3 and / or SIB4, and the detected received signal strength information is compared with a preset threshold. When the received signal strength information is greater than or equal to the threshold as a result of the comparison, an RRC connection request message and / or an RRC connection setup complete message to the first mobile communication network 270 for RRC connection. On the contrary, when the received signal strength information is smaller than the threshold value, the slave modem 220 determines whether the slave modem 220 is driven in the low power mode, and outputs a low power drive command to the slave modem 220 when the slave modem 220 is not driven in the low power mode. .

In addition, in a traffic state (that is, a state where the master modem 210 performs an operation such as communication and / or data transmission and reception), the received signal strength information among the radio station information received from the first mobile communication network 270 is displayed. As a result of the detection and comparison with the threshold value, when the received signal strength information is greater than or equal to the threshold value, the slave modem 220 determines whether the slave modem 220 is being driven in the low power mode, and if it is being driven in the low power mode (LPM), the slave modem 220 In response to outputting a driving termination command, if the received signal strength information is less than the threshold value, the slave modem 220 determines whether the low power mode is being driven. Output Here, the driving termination means that the slave modem 220 is electrically turned off by completely cutting off the power supplied to the slave modem 220. In the present specification, the driving termination is interpreted to have the same meaning as the off state.

In this case, the received signal strength information is a received signal code power (RSCP) value and / or energy-to-noise ratio (Ec / Io) received from the WCDMA mobile communication network when the master modem 210 is a WCDMA modem Can be.

The slave modem 220 processes various signals of base bands when the MB-MM mobile communication terminal 200 operates in a slave mode (that is, a communication mode using a communication method according to the slave modem 220). And control. In particular, when power is applied while the MB-MM mobile communication terminal 200 is located in the service area of the second mobile communication network 280 (Power on), an initial searching is performed to perform a second mobile communication network 270. ) Is driven to an idle state. In addition, when the low power drive command is received from the master modem 210, the drive is started in a low power mode (LPM). In addition, when the driving termination command is received from the master modem 210 in the low power mode, the driving is terminated. In addition, when the drive is driven in the low power mode in response to the low power drive command or the drive is terminated in response to the drive termination command, an acknowledgment (ACK) signal may be output to the master modem 210.

The master high frequency processor 230 includes a receiving end for processing a signal received from the first mobile communication network 270 and a transmitting end for processing a signal transmitted from the master modem 210 to the first mobile communication network 270. The 210 processes various high frequencies of the master mode transmitted and received, such as amplifying a signal output to the network. In particular, the wireless station information transmitted from the first mobile communication network 270 is received and output to the master modem 210.

The slave high frequency processor 240 includes a receiving end for processing a signal received from the second mobile communication network 280 and a transmitting end for processing a signal output from the slave modem 220 to the second mobile communication network 280, and a slave modem. The 220 amplifies a signal output to the second mobile communication network 280 and processes various high-frequency signals in the slave mode transmitted and received.

The control path 250 is a path for data exchange between the master modem 210 and the slave modem 220. In particular, the master modem 210 may output a low power drive command and a drive end command to the slave modem 220 through the control path 250. In addition, the slave modem 220 may output an acknowledgment (ACK) signal to the master modem 210 via the control path 250.

The storage unit 255 is connected to the master modem 210, and various kinds of necessary when the MB-MM mobile communication terminal 200 operates in a master mode (that is, a mode for performing communication by the master modem 210). Save the parameters. In particular, a preset threshold value is stored for comparison with the received signal strength information.

The duplexer 260 separates different high frequency bands of the respective modes, and the antenna 265 transmits signals from the MB-MM mobile communication terminal 200 and the first and / or second mobile communication networks 270 and 280. Send and receive

As shown in FIG. 2, the first mobile communication network 270 includes a first network radio station controller (RNC) 271 and a first mobile switching center (hereinafter referred to as 'RNC'). MSC ') (272). In addition, the first mobile communication network 270 may further include a packet data service node (PDSN).

The first network RNC 271 controls a base station (BS) (not shown) that performs wireless communication with the master modem 210 of the MB-MM mobile communication terminal 200. In particular, the radio station is controlled so that the radio station transmits radio station information (for example, a system information block (SIB), etc.) to the MB-MM mobile communication terminal 200 (that is, the master modem 210).

Of course, various signals (especially radio station information) output from the first mobile communication network 270 to the master modem 210 may be controlled by the first network RNC 271 to control the radio station communicating with the master modem 210. It outputs to the master modem 210. However, it will be described that the first mobile communication network 270 outputs various signals to the master modem 210 for convenience of understanding and explanation. On the contrary, even when the master modem 210 outputs a signal to the first mobile communication network 270, the master modem 210 is outputted to the first network RNC 271 through a wireless station. It will be described as outputting signals to the first mobile communication network 270.

Accordingly, when the first mobile communication network 270 outputs information on the radio station to the master modem 210 and receives the RRC connection request message from the master modem 210, the first mobile communication network 270 sends the RRC connection establishment message to the master modem 210. Will print

The first network MSC 272 manages various identifiers for the MB-MM mobile communication terminal 200 and the MB-MM mobile communication terminal when the MB-MM mobile communication terminal 200 is located in the first mobile communication network 270. 200 Search and track.

In addition, as shown in FIG. 2, the second mobile communication network 280 includes a second network base station controller (hereinafter referred to as a "BSC") 281 and a second network MSC 282. . The second mobile communication network 280 may further include a Serving GPRS Support Node (SGSN).

The second network BSC 281 controls a base station (not shown) that performs wireless communication with the slave modem 220 of the MB-MM mobile communication terminal 200.

The second network MSC 282 manages various identifiers for the MB-MM mobile communication terminal 200 and the MB-MM mobile communication terminal when the MB-MM mobile communication terminal 200 is located in the second mobile communication network 280. 200 Search and track.

Hereinafter, a method of driving a modem in an MB-MM mobile communication terminal according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4.

3 is a flowchart illustrating a modem driving method in an MB-MM mobile communication terminal according to an embodiment of the present invention.

Before describing with reference to FIG. 3, it is assumed that the slave modem 220 of the MB-MM mobile communication terminal 200 is in a driving termination state. If the slave modem 220 is already driving in the low power mode, it will be described later with reference to FIG. 4.

First, when the master modem 210 of the MB-MM mobile communication terminal 200 operating in the idle state in the service area of the first mobile communication network 270 has a need for an RRC connection for wireless communication (this At this time, the slave modem 220 detects received signal strength information from wireless station information (for example, a system information block (SIB), etc.) received from the first mobile communication network 270. (Steps 300-315). The received signal strength information may be received signal code power (RSCP) and / or energy to noise ratio (Ec / Io). In addition, when there is a need for an RRC connection, the data should be output to the first mobile communication network 270 due to a user's call attempt, or the like, when the data should be received from the first mobile communication network 270. can do.

In operation 320, the master modem 210 compares the extracted received signal strength information with a preset threshold. Here, the threshold value may be stored in the storage unit 255. However, the threshold value does not necessarily need to be stored in the storage unit 255. That is, the threshold value may be stored in any storage area (for example, a storage unit provided in the master modem) accessible by the master modem 210.

As a result, when the received signal strength information is smaller than the threshold value, the master modem 210 receives a handover to the slave modem 220 after the RRC connection is made because the strength of the signal received from the first mobile communication network 270 is weak. It is a case where there is a high possibility to perform. Therefore, in this case, in order to perform a smooth handover, the slave modem 220 must be driven in a low power mode. That is, in step 325, the master modem 210 determines whether the slave modem 220 is driven in the low power mode, and outputs a low power drive command to the slave modem 220 when the slave modem 220 is not driven in the low power mode ( Step 330).

In operation 335, the slave modem 220 receives the low power driving command and starts driving in the low power mode. Here, the low power mode means that the power of the CDMA modem is applied, but does not perform a communication function, and the current consumption is about 1 mA to 1.5 mA, which means that the current consumption is lower than that of the conventional idle state. . In this specification, the low power mode is used in the same sense as the low power standby state and the low power state. The slave modem 220 started in the low power mode may output an acknowledgment (ACK) signal to inform the master modem 210 of the result of being driven in the low power mode (not shown). Alternatively, if there is no acknowledgment (ACK) signal for a preset time after the master modem 210 outputs the low power driving command, the master modem 210 may predetermine that the acknowledgment (ACK) signal is present.

However, when the determination result in step 320 indicates that the received signal strength information is greater than or equal to the threshold value and / or when the slave modem 220 is driven in the low power mode as a result of the determination in step 325, the low power driving command is output to the slave modem 220. There is no need to do it. That is, there is no need to perform steps 330 to 335.

In operation 340, when the slave modem 220 is operating in the low power mode or the received signal strength information is greater than or equal to the threshold value, the master modem 210 may transmit an RRC connection request message to acquire a radio resource. Is output to the first mobile communication network 270. In this case, the RRC connection request message includes an initial UE identity of the UE and an RRC establishment cause. The initial terminal identifier is a terminal unique identifier, so that the terminal can be identified anywhere in the world. There are various reasons for RRC connection, for example, a user's call attempt.

In operation 345, the master modem 210 receives an RRC connection setup message from the first mobile communication network 270. If the master modem 210 does not receive the RRC connection establishment message for a preset time, it may reprint the RRC connection request message. At this time, the maximum number of output of the RRC connection request message may be limited to a specific value. In this case, the RRC connection setup message may include a radio network temporary identity (RNTI) and a radio bearer setup information together with the initial terminal identifier. The radio network temporary identifier is a terminal identifier assigned by the first mobile communication network 270 to identify a terminal in a connected state, and may be used only when an RRC connection exists. As described above, after the RRC connection is established, the master modem 210 may communicate with the first mobile communication network 270 using the wireless network temporary identifier instead of the initial terminal identifier, because the initial terminal identifier may be unique to the terminal. It is an identifier because it can be leaked if used frequently. Therefore, for security reasons, the initial terminal identifier may be used only for the RRC connection process for a while, and then the temporary network identifier may be used.

Receiving the connection establishment message, the master modem 210 first compares its identifier with the initial terminal identifier included in the message, and checks whether the received message is a message output to itself. If the message is output to the self as a result of the check, the master modem 210 stores the radio network temporary identifier assigned by the first mobile communication network 270, and uses it to provide an RRC connection setup complete message. 1 output to the mobile communication network 270 (step 350). In this case, the RRC connection setup complete message may include performance information of the MB-MM mobile communication terminal 220.

When the master modem 210 successfully outputs the RRC connection establishment complete message to the first mobile communication network 270, the master modem 210 completes the RRC connection establishment.

4 is a flowchart illustrating a modem driving method in an MB-MM mobile communication terminal according to another preferred embodiment of the present invention.

Hereinafter, a modem driving method in an MB-MM mobile communication terminal according to another preferred embodiment of the present invention will be described with reference to FIG. 4. Before describing with reference to FIG. 4, unlike the embodiment described with reference to FIG. 3, the slave modem 220 of the MB-MM mobile communication terminal 200 is assumed to be driven in a low power mode.

In operation 400, the master modem 210 of the MB-MM mobile communication terminal 200 is in an idle state and the slave modem 220 is operating in a low power mode.

Steps 410 to 420 are the same as or similar to steps 310 to 320 described above. Therefore, detailed description is omitted here.

As a result of the determination in step 420, when the received signal strength information is smaller than the preset threshold, it is necessary to operate the slave modem 220 in the low power mode for smooth handover as described above. Since the 220 is already driven in the low power mode, the master modem 210 may output an RRC connection request message directly to the first mobile communication network 270.

However, as a result of the determination in step 420, when the received signal strength information is greater than or equal to the threshold value, the slave modem 220 does not need to be driven in the low power mode. There is a need. This is because there is no possibility of handover because the communication state with the first mobile communication network 270 is good. Accordingly, when the received signal strength information is greater than or equal to the threshold value, the master modem 210 determines whether the slave modem 220 is being driven in the low power mode (step 425). If so, it outputs a drive termination command to the slave modem 220 (step 430).

In operation 435, the slave modem 220 receiving the driving termination command terminates the low power mode driving and transitions to the driving termination state. Here, the slave modem 220 that has been driven may output an acknowledgment (ACK) signal to inform the master modem 210 of the result of driving termination (not shown). Alternatively, if the acknowledgment (ACK) signal is not present for a predetermined time after the master modem 210 outputs the driving end command, the acknowledgment (ACK) signal may be determined in advance.

Steps 440 to 455 are the same as or similar to steps 340 to 355, and thus detailed descriptions thereof are omitted here.

3 and / or 4 illustrate the case where the master modem 210 needs to register a location with the first mobile communication network 270 in an idle state, the master modem 210 is traffic. It is apparent to those skilled in the art that the present invention may be applied to the same or similarly in the case of the state, that is, even in the state of performing wireless communication with the first mobile communication network 270. For example, the master modem 210 continuously receives the received signal strength information from the first mobile communication network 270 even in a traffic state, and compares the received received signal strength information with a preset threshold to the slave modem 220. It is possible to determine whether to operate the low power mode. However, in this case, since the master modem 210 is already in the RRC connection state, a process of outputting a signal such as an RRC connection request message to the first mobile communication network may be omitted.

As described above, in the method of driving a modem in an MB-MM mobile communication terminal and an MB-MM mobile communication terminal according to the present invention, an MB-MM mobile communication terminal including a first modem and a second modem is used only in a first mobile communication network. When performing wireless communication, there is an effect that the second modem can be restricted from being driven in the low power mode.

In addition, the present invention, when the MB-MM mobile communication terminal 120 including the first modem and the second modem performs wireless communication in the first mobile communication network, unnecessary unnecessary caused by driving the second modem in a low power mode It also has the effect of preventing power consumption.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be appreciated that modifications and variations can be made.

Claims (16)

And a first modem and a second modem for performing wireless communication with the first mobile communication network and the second mobile communication network, respectively, and wirelessly communicating with the first mobile communication network in an overlay area by the first mobile communication network and the second mobile communication network. In the MB (Multiband) -MM (Multimode) mobile communication terminal for switching the power consumption state of the second modem by the first modem performing a communication, The first modem performs wireless communication with the first mobile communication network and compares the received signal strength information received from the first mobile communication network with a preset threshold value, wherein the preset threshold value is a power consumption state of the second modem. Used to determine If the received signal strength information is greater than the threshold value, the power of the second modem is cut off so that the second modem is turned off. If the received signal strength information is less than the threshold value, the second modem is previously set. The second modem is controlled to be switched to a low power state by applying power below a set level, wherein the off state and the low power state are states in which wireless communication with the second mobile communication network is not performed. And the switching between the off state and the low power state of the second modem is made while the first modem performs wireless communication with the first mobile communication network. The method of claim 1, And the first modem controls the second modem to switch to a low power state only when the second modem is in the off state. delete delete The method of claim 1, The received signal strength information MB-MM mobile terminal, characterized in that the received signal code power (Received Signal Code Power). delete delete delete delete A multi-band (MB) -MM (multimode) mobile communication terminal including a first modem and a second modem for wirelessly communicating with a first mobile communication network and a second mobile communication network, respectively, the first mobile communication network and the second mobile communication network. A method for switching a power consumption state of a second modem by a first modem performing wireless communication with a first mobile communication network in an overlay area by: Comparing the received signal strength information received from the first mobile communication network with a preset threshold while performing wireless communication with the first mobile communication network, wherein the preset threshold is power consumption of the second modem; Used to determine status; And If the received signal strength information is greater than the threshold value, the power applied to the second modem is cut off so that the second modem is turned off. If the received signal strength information is less than the threshold value, the second modem is controlled. Controlling the second modem to be switched to a low power state by applying power below a predetermined level, wherein the off state and the low power state cannot perform wireless communication with the second mobile communication network. Including; Switching between the off state and the low power state of the second modem is performed while the first modem performs wireless communication with the first mobile communication network. The method of claim 10, The controlling of switching to the low power state further includes determining whether the second modem is in the off state when the received signal strength information is smaller than the threshold value. And the first modem controls the second modem to be switched to the low power state only when the second modem is in an off state. delete The method of claim 10, The received signal strength information is a method of switching a power consumption state of a second modem, characterized in that the received signal code power (Received Signal Code Power). delete delete delete

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