KR20070009333A - Method for transmitting authentication information in multi-mode mobile - Google Patents

Abstract

An apparatus for transmitting terminal authentication information in a multi-mode mobile terminal is provided to transmit the terminal authentication information by the other RAT to a corresponding RAT base station by using CDMA(Code Division Multiple Access) terminal authentication information pre-stored in a non-volatile memory of a WCDMA(Wideband CDMA) modem when the mobile terminal is being operated in one RAT mode, thereby preventing power consumption required to boot a CDMA modem and fetch the CDMA terminal authentication information. In a multi-mode mobile terminal supporting at least first and second RAT(Radio Access Technology) modes, an apparatus for transmitting terminal authentication information comprise the first and second modem blocks(500,502) each operating according to the first and second RAT modes. The first modem block(500) includes a non-volatile memory(506) which stores the first terminal authentication information by the first RAT and the second terminal authentication information by the second RAT. The second modem block(502) includes the second non-volatile memory(518) which stores the second terminal authentication information.

Description

Terminal authentication information transmission device in a multi-mode mobile terminal {METHOD FOR TRANSMITTING AUTHENTICATION INFORMATION IN MULTI-MODE MOBILE}

1 is a block diagram of a multi-mode mobile terminal;

2 is a procedure showing an RRC connection setup process;

3 is a procedure showing a terminal capability information transmission process;

4 is a procedure showing a conventional terminal authentication information transfer process,

5 is a block diagram of a modem unit according to an embodiment of the present invention;

6 is a procedure showing an RRC connection setup process according to an embodiment of the present invention;

7 is a procedure showing a terminal capability information delivery process according to an embodiment of the present invention.

The present invention relates to a multi-mode mobile terminal supporting different radio access technologies (RATs), and in particular, an apparatus for transmitting terminal authentication information to a base station for inter-radio access technology (RAT) handover. It is about.

In the mobile communication network, the second generation code division multiple access (CDMA) network is evolving into a wideband code division multiple access (WCDMA) network, which is a third generation mobile communication service. In this process, WCDMA networks are being installed in some areas and gradually expanding the service area. As a result, there are currently fewer regions that can use WCDMA than regions that can use CDMA.

In view of this, a mobile terminal supporting WCDMA is manufactured as a multi-mode mobile terminal supporting a second generation CDMA, that is, a different radio access technology (RAT) mode, and can switch between WCDMA and CDMA modes. It has a roaming function. However, the roaming function is an idle handover function that switches the mode from the standby state. Accordingly, when the mobile station calls in the WCDMA mode in the area where WCDMA and CDMA are installed at the same time and enters the shadow area in which only the CDMA mode is serviced without WCDMA installed, the call is disconnected and then switched to the CDMA mode from the standby state. This disconnection is very inconvenient for the user using the multi-mode.

One way to alleviate this inconvenience is to install many WCDMA base stations to eliminate all WCDMA shadow areas. However, since the investment of the operators is made gradually, it requires a lot of money and time. As another method, using a conventional CDMA network, when entering a WCDMA shadow area during a call, the mobile terminal receives a signal from the base station and performs a traffic handover that seamlessly switches to CDMA mode. This scheme is much more economical because it can utilize existing CDMA networks, but the hardware and software of the mobile terminal need to be handed over between different modems (MODEM: Modulator-Demodulator), that is, WCDMA and CDMA modems. It gets complicated.

As an example of a multi-mode mobile terminal, a dual mode mobile terminal supporting WCDMA mode and CDMA mode is basically implemented as a dual modem mobile terminal having a WCDMA modem 108 and a CDMA modem 104, as shown in FIG. . And an application processor 112, which is a multimedia chip for coordinating the two and processing the received and transmitted data.

As shown in FIG. 1, the WCDMA modem 108 and the application processor 112 are connected by a hardware communication path, and the CDMA modem 104 and the application processor 112 are also connected by a hardware communication path. In this case, the communication port of the application processor 112 is connected to either the CDMA modem 104 or the WCDMA modem 108 using the switch 110. The modem used among the CDMA modem 104 and the WCDMA modem 108, that is, the modem corresponding to the RAT currently selected between CDMA and WCDMA and the application processor 112 correspond 1: 1 in this port and are not used. Keeps the power off during this time to prevent power consumption.

The diplexer 100 is used when a dual mode mobile terminal is implemented using a single antenna as shown in FIG. 1, and separates WCDMA and CDMA signals transmitted and received through the antenna. The CDMA Radio Frequency (RF) block 102 is an RF block that processes CDMA signals at the antenna stage. Signals transmitted or received via the CDMA RF block 102 are processed by the CDMA modem 104. The WCDMA RF block 106 is an RF block that processes WCDMA signals at the antenna stage. Signals transmitted or received via the WCDMA RF block 106 are processed by the WCDMA modem 108.

If the mobile terminal is in a WCDMA network, the CDMA RF block 102 and the CDMA modem 104 are temporarily turned off. The diplexer 100, the WCDMA RF block 106, the WCDMA modem 108, and the application processor 112 are turned on, and the switch 110 connects the WCDMA modem 108 and the application processor 112 to each other. The mobile terminal operates as a WCDMA mobile terminal. If the mobile terminal is only in the CDMA network, then WCDMA RF block 106 and WCDMA modem 108 are temporarily turned off. The diplexer 100, the CDMA RF block 102, the CDMA modem 104, and the application processor 112 are turned on, and the switch 110 connects the CDMA modem 104 and the application processor 112 to each other. The mobile terminal acts as a CDMA mobile terminal.

While the mobile terminal is operating in the WCDMA mode, the WCDMA base station must deliver the information of the mobile terminal to the CDMA base station in order to perform inter-RAT traffic handover in the CDMA mode. For this purpose, the WCDMA base station must know the CDMA modem information. The CDMA modem information means unique CDMA terminal authentication information for identifying a terminal in CDMA, such as an electronic serial number (ESN) and an international mobile subscriber identity (IMSI). Currently, ESN is used as CDMA terminal authentication information, but the usage of ESN is congested worldwide, and the assigned number is exhausted, and may be changed later by other methods such as manufacturer equipment identifier (MEID). Therefore, in the present specification, the CDMA terminal authentication information is described as meaning the ESN used in the current terminal authentication scheme, but when the terminal authentication scheme is changed, the terminal authentication information used accordingly may also be changed.

As such, since the WCDMA base station needs to know the CDMA terminal authentication information for the RAT traffic handover, the mobile terminal transmits the CDMA terminal authentication information to the WCDMA base station. When the mobile terminal operating in the WCDMA mode transmits a Radio Resource Control (RRC) connection setup complete message to the base station or transmits an RRC connection setup complete or a UE capability information message UE Capability Information, the UE capability information message UE Capability Information CDMA terminal authentication information should be included in the IS2000 field and transmitted to the base station.

This will be described with reference to FIG. 2 showing the RRC connection setup process and FIG. 3 showing the terminal capability information transmission process as follows. 2 and 3, the user equipment (UE) 200 is a dual mode mobile terminal as shown in FIG. 1, and the UTRAN (UMTS Terrestrial Radio Access Network) 202 is a WCDMA network. The UE 200 is connected with the WCDMA base station of the UTRAN 202.

First, referring to FIG. 2, when the UE 200 transmits an RRC connection request message RRC Connection Request to the UTRAN 202 in step 300, the UTRAN 202 sends an RRC connection setup message RRC Connection Setup in step 302. To the UE 200. Then, the UE 200 transmits the RRC connection setup complete message RRC Connection Setup Complete to the UTRAN 202 in step 304 in response to the RRC connection setup message RRC Connection Setup. In this case, the UE 200 includes the CDMA terminal authentication information in the Inter-RAT UE Access Capability IE field of the RRC connection setup complete message RRC Connection Setup Complete and provides the WCDMA base station of the UTRAN 202.

Next, referring to FIG. 3, after the RRC connection setup is made as described above, the UTRAN 202 transmits a UE capability inquiry message UE Capability Inquiry to the UE 200 in step 310. Then, the UE 200 transmits the UE capability information message UE Capability Information to the UTRAN 202 in step 312. At this time, the UE 200 includes the CDMA terminal authentication information in the Inter-RAT UE Access Capability IE field of the UE capability information message UE Capability Information and provides it to the WCDMA base station of the UTRAN 202.

On the other hand, when the mobile terminal is booted in the WCDMA mode, the RAM (Random Access Memory) area of the WCDMA modem 108 is read by reading an ESN, which is CDMA terminal authentication information stored in a non-volatile memory of the CDMA modem 104. Stored in and used. However, when the information is stored in RAM, which is volatile memory, the stored information is also erased when the power is turned off. Accordingly, after booting into the WCDMA mode or after switching from the CDMA mode to the WCDMA mode, the CDMA modem 104 must also be rebooted so that the WCDMA modem 108 can obtain CDMA terminal authentication information from the CDMA modem 104.

As shown in FIG. 4, the WCDMA modem 108 obtains CDMA terminal authentication information from the CDMA modem 104 and transmits the CDMA terminal authentication information to the WCDMA base station. After booting in the WCDMA mode, the WCDMA modem 108 requests the application processor 112 to boot the CDMA modem 104 in step 400. The application processor 112 then powers on the CDMA modem 104 in step 402.

As such, when the CDMA modem 104 is powered on, the CDMA modem 104 notifies the WCDMA modem 108 at step 404 after it is booted. The WCDMA modem 108 then requests the CDMA terminal authentication information ESN from the CDMA modem 104 in step 406. In response, the CDMA modem 104 notifies the WNDMA modem 108 of the ESN in step 408. The WCDMA modem 108 stores the ESN obtained from the CDMA modem 104 in RAM and requests the application processor 112 to power off the CDMA modem 104 in step 410. Accordingly, the application processor 112 turns off the power of the CDMA modem 104 in step 412.

Thereafter, the WCDMA modem 108 sends an RRC connection setup complete message to the WCDMA base station of the UTRAN 202 in the steps 414 and 418 corresponding to the steps 300 and 302 of FIG. 2 described above. The CDMA terminal authentication information is included and sent. In this case, the CDMA terminal authentication information transmitted by the WCDMA modem 108 to the WCDMA base station is ESN and IMSI. Typically, IMSI also has a WCDMA modem 108, so only the ESN is transmitted from the CDMA modem 104 in step 408. To bring.

As described above, in the multi-mode mobile terminal, each terminal authentication information according to each RAT mode is stored only in the nonvolatile memory of each modem. When booting in any one of the RAT modes, the RAT mode modem in operation is changed to another RAT. I booted the modem in mode and got terminal authentication information according to different RATs from it and stored it in volatile memory.

Accordingly, power consumption is generated in booting modems of different RAT modes to obtain terminal authentication information according to different RATs, which shortens battery power life time.

In addition, it takes time for the operating RAT mode modem to obtain terminal authentication information from another RAT mode modem for inter-RAT traffic handover. When the terminal authentication information in the RAT mode is requested, the terminal authentication information may not be delivered in a timely manner.

Accordingly, the present invention provides an apparatus capable of efficiently and accurately transmitting terminal authentication information of another RAT mode to a base station in operation in a multi-mode mobile terminal supporting at least two or more RAT modes.

In addition, the present invention reduces the power consumption and time required for the RAT mode modem operating in a multi-mode mobile terminal supporting at least two RAT modes to transmit terminal authentication information of another RAT mode to the base station of the RAT mode in operation. It provides a device that can.

To this end, according to an aspect of the present invention, in a multi-mode mobile terminal supporting at least the first and second RAT modes, the first and second modem blocks respectively operating according to the first and second RAT modes. And a first nonvolatile memory in which the first modem block stores first terminal authentication information according to the first RAT and the second terminal authentication information according to the second RAT, and the second modem block includes a second terminal authentication. And a second nonvolatile memory having stored therein information, wherein the first modem block receives the second terminal authentication information from the first nonvolatile memory for inter-RAT handover to the second RAT while the mobile terminal is operating in the first RAT mode. Read and deliver to the base station of the first RAT.

In accordance with another aspect of the present invention, a multi-mode mobile terminal supporting at least a first and a second RAT mode, the first and second modem blocks respectively operating according to the first and second RAT modes, The first and second modem blocks each include first and second nonvolatile memories in which terminal authentication information according to the first RAT and terminal authentication information according to the second RAT are stored, and the mobile terminal is in the first and second RAT modes. During operation in one of the RAT modes, the modem block among the first and second modem blocks reads the terminal authentication information according to the other RAT from the nonvolatile memory provided by the modem block among the first and second modem blocks for handover between RATs during the call. It transmits to the corresponding base station of the first and second RAT.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the annexed drawings, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted. In addition, hereinafter, the present invention will be described as an example of applying the present invention as a multi-mode mobile terminal to a dual-mode dual modem mobile terminal having a WCDMA modem and a CDMA modem and supporting WCDMA and CDMA.

According to an embodiment of the present invention, unique CDMA terminal authentication information such as ESN is not stored in the volatile memory area of the WCDMA modem of the mobile terminal from the CDMA modem. Instead, the space for storing CDMA terminal authentication information is pre-allocated in the nonvolatile memory area of the WCDMA modem where the contents of the WCDMA modem are stored even when the power is turned off. The process is also added to the volatile memory area. In addition, when updating the CDMA terminal authentication information, the WCDMA modem is also updated in the same manner. This eliminates the need for the WCDMA modem to turn on the CDMA modem and request CDMA terminal authentication information.

FIG. 5 is a block diagram of a modem unit according to an exemplary embodiment of the present invention. Each of the WCDMA modem 504 and the CDMA modem 516 corresponding to the WCDMA modem 108 and the CDMA modem 104 of FIG. The WCDMA modem block 500 and the CDMA modem block 502 are shown.

In the WCDMA modem block 500 of FIG. 5, the WCDMA modem 504 is basically a central processing unit (CPU) 510, a digital signal processor (DSP) 512, and a read only memory (ROM) 514. It is configured and has an external EEPROM (Electrically Erasable and Programmable ROM) 506 and a RAM 508 that are nonvolatile memories. Similarly, in the CDMA modem block 502, the CDMA modem 516 also includes the CPU 522, the DSP 524, and the ROM 526, and has an EEPROM 518 and a RAM 520 externally.

The basic configuration of the WCDMA modem block 500 and the CDMA modem block 502 is similar to a dual mode mobile terminal with a conventional dual modem. However, the EEPROM 506 of the WCDMA modem block 500 stores not only WCDMA terminal authentication information but also CDMA terminal authentication information according to an embodiment of the present invention.

In general, since data stored in the EEPROMs 506 and 518 are maintained even when the modem is powered off, a binary image of the modem is stored, and a part of the area is allocated as an area for storing constant values used in the binary image. As one of these areas, terminal authentication information storage areas 528 and 530 are allocated to each of the EEPROMs 506 and 518, WCDMA terminal authentication information is stored in the terminal authentication information storage area 528, and terminal authentication information storage area 530 is stored in the terminal authentication information storage area 530. CDMA terminal authentication information is stored. Here, as the WCDMA terminal authentication information, not only the IMSI included in the CDMA terminal authentication information but also the IMEI (International Mobile Equipment Identity) is used.

Meanwhile, the terminal authentication information storage area 528 of the EEPROM 506 additionally stores not only WCDMA terminal authentication information but also CDMA terminal authentication information according to an embodiment of the present invention. That is, the CDMA terminal authentication information stored in the terminal authentication information storage area 530 of the EEPROM 518 is also stored in the terminal authentication information storage area 528 of the EEPROM 506. This is done in the manufacturing process of the mobile terminal as described above. In addition, when the CDMA terminal authentication information is updated, the WCDMA modem is also updated.

As described above, a process of transferring CDMA terminal authentication information stored in the WCDMA modem block 500 to the WCDMA base station according to an embodiment of the present invention is shown as FIGS. 6 and 7 respectively corresponding to FIGS. 2 and 3. In FIGS. 6 and 7, the WCDMA modem 504 is described instead of the UE 200 in FIGS. 2 and 3. However, the WCDMA modem 504 may be configured to transmit UE authentication information according to an embodiment of the present invention. It is to make it easy to understand what is done by.

First, referring to FIG. 6, when the WCDMA modem 504 transmits an RRC connection request message RRC Connection Request to the UTRAN 202 in step 600, the UTRAN 202 sends an RRC connection setup message RRC connection in step 602. Send Setup to WCDMA modem 504. The WCDMA modem 504 then reads the CDMA terminal authentication information from the terminal authentication information storage area 528 of the EEPROM 506 in step 604. Next, the WCDMA modem 504 includes the CDMA terminal authentication information read from the terminal authentication information storage area 528 in the Inter-RAT UE Access Capability IE field of the RRC connection setup complete message RRC Connection Setup Complete in step 606. To the WCDMA base station of the UTRAN 202.

Next, referring to FIG. 7, after the RRC connection setup is performed as described above, the UTRAN 202 transmits the UE capability inquiry message UE Capability Enquiry to the WCDMA modem 504 in step 700. The WCDMA modem 504 then reads the CDMA terminal authentication information from the terminal authentication information storage area 528 of the EEPROM 506 in step 702. Next, the WCDMA modem 504 includes the CDMA terminal authentication information read out from the terminal authentication information storage area 528 in the Inter-RAT UE Access Capability IE field of the UE capability information message UE Capability Information in step 704. To the WCDMA base station (202).

Therefore, in a multi-mode mobile terminal supporting CDMA and WCDMA, when the mobile terminal operates in the WCDMA mode and needs to transmit CDMA terminal authentication information to the WCDMA base station, the CDMA modem is not turned on to bring the information. Instead, it is transmitted using CDMA terminal authentication information stored in the nonvolatile memory of the WCDMA modem in advance.

This eliminates the need to turn on the CDMA modem to retrieve CDMA terminal authentication information as shown in FIG. 4 described above. Accordingly, not only the power consumption due to the booting of the CDMA modem and the operation of obtaining the CDMA terminal authentication information can be prevented, but also the CDMA terminal information can be delivered without delay when the WCDMA base station requests the CDMA terminal authentication information.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications may be made within the scope of the present invention.

In particular, in the embodiment of the present invention, in the WCDMA modem block 500, the terminal authentication information storage area 528 for storing the CDMA terminal authentication information is allocated to the EEPROM 506, but is allocated to the ROM 514. You may.

In addition, although the example of performing the RAT traffic handover from the WCDMA mode to the CDMA mode has been described, the same applies to the case of the RAT traffic handover from the CDMA mode to the WCDMA mode. In this case, not only the CDMA terminal authentication information but also the WCDMA terminal authentication information is stored in the terminal authentication information storage area 530 of the CDMA modem 502, so that the CDMA modem 502 performs handover between RATs from the CDMA mode to the WCDMA mode. In this case, it can be delivered to the CDMA base station.

Although the present invention is an example of applying the present invention to a dual mode mobile terminal supporting WCDMA and CDMA, other RATs such as Global System for Mobile communication (GSM) / General Packet Radio Services (GPRS) and Universal Mobile Telecommunication Service (UMTS) The same applies to the mobile terminal supporting the dual mode. In addition, the same may be applied to a multi-mode mobile terminal supporting three or more RATs as well as a mobile terminal supporting two RATs.

In addition, although the example is applied to the case of transmitting the terminal authentication information for traffic handover, it is usefully applied if it is necessary to deliver the terminal authentication information according to different RAT modes, such as idle handover.

Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the equivalents of the claims and claims.

As described above, in the multi-mode mobile terminal, when the mobile terminal operates in one RAT mode and needs to transmit terminal authentication information according to another RAT to the corresponding RAT base station, the non-volatileness of the WCDMA modem in advance. Transfer using CDMA terminal authentication information stored in the memory.

This eliminates the need to turn on the CDMA modem to retrieve CDMA terminal authentication information, thereby preventing power consumption due to booting of the CDMA modem and obtaining CDMA terminal authentication information, and the WCDMA base station to authenticate the CDMA terminal. The CDMA terminal information can be delivered without delay at the time of requesting the information.

Claims (5)

In the multi-mode mobile terminal that supports at least the first and second RAT (Radio Access Technology) mode, And first and second modem blocks operating according to the first and second RAT modes, respectively. The first modem block includes a first nonvolatile memory in which first terminal authentication information according to the first RAT and second terminal authentication information according to the second RAT are stored; The second modem block includes a second nonvolatile memory in which the second terminal authentication information is stored; The first modem block reads the second terminal authentication information from the first non-volatile memory for inter-RAT handover to the second RAT while the mobile terminal is operating in the first RAT mode, and thus the first RAT. Device for transmitting terminal authentication information, characterized in that for transmitting to the base station. The apparatus of claim 1, wherein the first RAT is Wideband Code Division Multiple Access (WCDMA) and the second RAT is Code Division Multiple Access (CDMA). The mobile station of claim 2, wherein the first modem block includes the second terminal authentication information in an RRC connection setup complete message when the RRC connection is set up, and transmits the terminal information to the base station of the first RAT. And transmitting the information to the base station of the first RAT by including the information in the terminal capability information. In the multi-mode mobile terminal that supports at least the first and second RAT (Radio Access Technology) mode, And first and second modem blocks operating according to the first and second RAT modes, respectively. Each of the first and second modem blocks includes first and second nonvolatile memories storing terminal authentication information according to the first RAT and terminal authentication information according to the second RAT. While the mobile terminal is operating in any one of the first and second RAT modes, the non-owned modem block among the first and second modem blocks for the handover between RATs to another RAT is provided by the mobile terminal. The terminal authentication information transmission device, characterized in that for reading the terminal authentication information according to the other RAT from the volatile memory to the corresponding base station of the first and second RAT. 5. The apparatus of claim 4, wherein the first RAT is Wideband Code Division Multiple Access (WCDMA) and the second RAT is Code Division Multiple Access (CDMA).

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