KR20120124323A - Apparatus having Universal Integrated Circuit card and File registration Method and Peer-to-Peer Transmission Method using the same - Google Patents

Abstract

PURPOSE: An apparatus having an UICC(universal integrated circuit card) and a file registration method and a peer-to-peer transmission method using the same are provided to support peer-to-peer communications by Bluetooth or WiFi by using a file stored in the UICC. CONSTITUTION: A transmission terminal operates a user interface or a peer to peer transmission application(S410). A NFC(Near Field Communication) module of the transmission terminal is executed in a NFC reader mode(S420). The transmission terminal transfers a MAC(Medium Access Control) address request message to a receiving terminal(S430). The receiving terminal transmits MAC address information to the transmission terminal(S440). The transmission terminal executes Bluetooth pairing or WiFi pairing(S450). The transmission terminal transfers massive data to the receiving terminal through a Bluetooth module or a WiFi module(S460). [Reference numerals] (AA) Transmission terminal; (BB) Receiving terminal; (DD,EE) BT/WiFi module; (S410) P2P Appl. execution; (S420,CC) NFC Reader mode execution; (S430) MAC address request message; (S440) MAC address information(EF_BT/WiFi_MacAddress); (S450) BT/WiFi Paring; (S460) P2P transmission by BT/WiFi

Description

Apparatus having Universal Integrated Circuit card and File registration Method and Peer-to-Peer Transmission Method using the same}

The present disclosure relates to a method and apparatus for transmitting and receiving large capacity data of a universal integrated circuit card (UICC), and after acquiring a MAC address (Media Access Control Address) of a corresponding NFC terminal when a session is connected in a near field communication (NFC) module, The present invention relates to a device and a method for transmitting / receiving a large amount of data between two terminals by a Bluetooth or WLAN (or WiFi) in a peer-to-peer (hereinafter referred to as P2P) scheme, and a file registration method therefor.

Recently, NFC has been discussed as a method of short-range wireless communication. NFC communication uses a 13.56 MHz frequency band (bandwidth of 14 kHz) between terminals equipped with an NFC module (hereinafter referred to as an NFC terminal) of up to 10 centimeters. It is a technology that transmits and receives data at a maximum speed of 424Kbps at close range.

NFC communication is largely defined to operate in three modes: card emulation mode, P2P mode, and reader / writer mode.

This NFC technology is an extension of the ISO / IEC 14443 access card standard that provides communication between a smart card and a reader within a single device. NFC communication has a relatively short setup time (within 0.1 seconds), but Not only is the communication distance shorter than 10 centimeters, but also the transmission speed is lower than that of Bluetooth or other short-range communication.

Meanwhile, the UICC used as a smart card in a wireless communication system such as GSM and Universal Mobile Telecommunication System (UMTS) is responsible for the integration and security of all kinds of personal information and usually has a capacity of several hundred KByte or more.

In addition, UICC includes Subscriber Identity Module (SIM) applications on GSM networks, Universal Subscriber Identity Module (USIM) applications on UMTS networks, and other applications that can access both GSM and UMTS networks, or address books (Phonebooks). ) Or as a storage space for other applications.

The standard specification currently under discussion is the Use Case of Contactless UICC Service of UICC, which includes ticket applications, payment applications, health care applications, and digital rights applications. , Retail applications, etc. are being discussed.

However, as UICCs become more and more large-capacity, discussions about large-capacity USIMs or large-scale UICCs are underway, and they can be used as a storage space for a large number of application information or other multimedia information in addition to information such as a conventional address book (Phonebook). There is an increasing need for transmitting and receiving stored large-capacity data between NFC terminals.

Accordingly, the present specification intends to propose a form of UICC usage with improved performance by combining data transmission technology of another short-range wireless communication with a short setup time and session connection between terminals, which is an advantage of NFC technology.

An object of the present invention is to provide a method for a terminal device including a UICC to support P2P communication by Bluetooth or WiFi using a file stored in the UICC.

The present invention is to provide a technology for storing the Bluetooth / Wi-Fi connection information of the terminal in the UICC.

The present invention provides a method for supporting P2P communication between two NFC terminals by using Bluetooth MAC address information or WiFi address information stored in the UICC.

An object of the present invention is to provide a method of acquiring Bluetooth MAC address information or WiFi address information of a counterpart terminal device in one step when NFC mode is executed, and using P2P to transmit large data such as multimedia address book information.

In order to achieve the above object, an embodiment of the present disclosure, in a terminal device including a universal integrated circuit card (UICC), the contactless front end interface (CLF) or CLFI protocol (CLFI Protocol) of the terminal device CLFIP) provides a terminal device that supports peer-to-peer mode communication using a file stored in the UICC and WiFi or Bluetooth.

According to another embodiment of the present invention, a terminal device including a Bluetooth module or a WiFi module and a Universal Integrated Circuit Card (UICC) for storing the MAC (Media Access Control) address information of the Bluetooth or the MAC address information of the WiFi is provided. do.

According to another embodiment of the present invention, a file registration method of a terminal device including a Bluetooth module or a WiFi module and a Universal Integrated Circuit Card (UICC), and when the terminal device is in a booting state, the Bluetooth of the Bluetooth module or the WiFi module is Obtaining MAC address information or WiFi address information, and storing the Bluetooth MAC address information or WiFi address information in the form of a basic file on the file structure of the UICC provides a file registration method.

According to another embodiment of the present invention, a Bluetooth module or a WiFi module, a Near Field Communication (NFC) module, P2P transmission information, and a Bluetooth Integrated Circuit Card (UICC) for storing the Bluetooth MAC address information or WiFi address information A P2P transmission method of a terminal device, the method comprising: generating and transmitting a MAC address request message requesting the other terminal device to transmit MAC address information of Bluetooth or MAC address information of WiFi when the NFC mode is executed; Receiving Bluetooth MAC address information of the counterpart terminal device or MAC address information of WiFi as a response to a MAC address request message; and using the Bluetooth MAC address information of the counterpart terminal device or the MAC address information of WiFi. Complete Bluetooth pairing or WiFi paying with terminal Then it provides the P2P transfer method comprising the step of performing the P2P transmission.

1 shows an overall configuration of a P2P communication system to which the present embodiment is applied.
2 illustrates an example of a UICC application structure applied to the present embodiment.
3 is a flowchart showing a file information registration process according to the present embodiment.
4 shows the overall signal flow of P2P communication according to the present embodiment.
5 is a block diagram of detailed functional block diagrams and data flows of a transmitting and receiving terminal apparatus according to an embodiment of the present invention.

Hereinafter, some embodiments will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present disclosure rather unclear.

In addition, the present specification describes a wireless communication system as an example, and the work performed in the wireless communication is characterized in that it includes all the operations performed in the system that controls the wireless communication and the wireless communication device that transmits data with the system.

Recently, the size of UICC memory is increasing very rapidly from Kbyte to Mbyte, which provides the possibility of extending the usage of UICC to new services.

The next generation service is based on multimedia content management, and it is expected to have a basic feature of storing multimedia content in the UICC such as MMS (Multimedia Messaging Service) storage.

In addition, it will be related to the transfer of large data between UICC or smart card, and for this purpose, the connection characteristics with the remote service inside and outside the terminal together with the fast data access technology that can avoid the time latency when using the service. Will be required.

However, as currently discussed, this trend is not reflected, and the UICC-terminal interface and protocol stack need to be modified according to the evolution of these services. Of course, these modifications should have backward compatibility.

As an example of an advanced service of the UICC, a multimedia file management function can be considered. The UICC can store multimedia files such as encrypted / decrypted MMS, MP3 files, video clips, and the like. Needs to be transferred quickly.

On the other hand, NFC communication has been proposed as one method for transmitting data between terminals, but in the following P2P data transmission by the NFC technology has the advantage that it has a relatively short setup time (within 0.1 seconds), Not only is the communication distance shorter than 10 centimeters, but also the transmission speed is lower than that of Bluetooth or other short-range communication. For reference, the data transmission rate by NFC is up to 484 Kbps, while Bluetooth can transmit data up to 2.1Mbps at a distance of 10 meters.

Therefore, an embodiment of the present invention provides a contactless front end (hereinafter referred to as "CLF") of a terminal including a UICC (CLF Interface; referred to as "CLFI") or CLFI protocol (CLFI Protocol; Hereafter, 'CLFIP' is configured to allow a system and a terminal including a UICC to support peer-to-peer mode communication using a USIM file and WiFi or Bluetooth. Here, the USIM file refers to a file for a specific purpose stored in the UICC. Specifically, the USIM file may be a basic file for storing Bluetooth MAC address information or WiFi address information.

Detailed configuration for this will be described in more detail with reference to Figure 1 below.

In the present specification, CLF refers to a component that can process an analog portion of contactless communication as a circuit in a terminal, can process some layers of a contactless protocol, and can be responsible for data processing between the terminal and the UICC.

In addition, CLFI means a physical interface between UICC and CLF, and CLFIP means a communication protocol between UICC and CLF through CLFI.

As mentioned above, the UICC, which is currently under discussion, is a use case of contactless UICC service, including a ticket application, payment application, health care application, and digital right. Requirements defined for the application, logistics application, etc. are shown in Table 1 below.

 Current UICC Contactless Requirements Identifier Requirement REQ15301 The CLFI and the CLFIP shall allow the system consisting of the UICC and the terminal to behave as a contactless card. REQ15302 The CLFI and the CLFIP shall allow the system consisting of the UICC and the terminal to behave as a contactless reader. REQ15303 The CLFI and the CLFIP shall allow the system consisting of the UICC and the terminal to support "peer to peer" mode as specified in ISO / IEC 18092 [9].

Such current REQ-7-15-03-01 to REQ-7-15-03-03 do not cover the environment for the transmission or exchange of large data on the UICC.

Thus, as in this embodiment, for fast session making and fast data transfer, the USIM or the P2P mode in addition to ISO / IEC 18092 defined in Requirement REQ-7-15-03-03 may be used. It is to define P2P transmission mode using UICC file and Bluetooth or WiFi together.

Requirements such as this embodiment may be defined, for example, such as multimedia address book sharing by contactless, but is not limited thereto, and the USIM or UICC file and the Bluetooth or WiFi together It may be defined in other terms as long as it means a contactless service of the P2P mode to be used.

However, hereinafter, the present embodiment will be described for the convenience of description by representing the multimedia address book sharing by contactless.

A system aspect of multimedia address book sharing by contactless will be described as follows.

Multimedia address books not only have large storage capacities, but also require a secure access mechanism. Not only does UICC have an ideal and suitable environment for storing a user's multimedia address book, but the user also needs to securely and quickly transmit his multimedia address book to another user or terminal.

Therefore, as described in the present embodiment, the request may be satisfied by establishing a session through the contactless interface of the UICC and transmitting or exchanging contents of the multimedia address book through a fast transmission medium such as Bluetooth or WiFi.

In this embodiment of the present invention, the role of the UICC or USIM may be defined as follows.

For reference, UICC is meant as a card having a plurality of applications, USIM means that is used for the purpose of subscriber identity (Subscriber Identity) of the communication. Therefore, in the present specification, UICC and USIM are used as equivalent concepts.

As a role of the UICC or USIM in the present embodiment, the UICC should store a unique Bluetooth or WiFi media access control (MAC) address and have a storage space for the multimedia address book received from the reader.

In addition, in the reader emulation mode of the NFC module, the UICC should include a multimedia address book transmitted to another UICC or a terminal.

Requirements for P2P communication using the USIM file and WiFi / Bluetooth according to the present embodiment may be defined as, for example, Table 2 below, but is not limited thereto.

Example of requirements of the service according to the present embodiment Identifier Requirement REQ153AA The CLFI and the CLFIP shall allow the system consisting of the UICC and the terminal to support "peer to peer" mode using a USIM file and WiFi or Bluetooth.

The detailed configuration of the P2P communication using the USIM (or UICC) file and WiFi / Bluetooth according to the present embodiment is as follows.

A large data transmission / reception method using a terminal storing MAC address information in a UICC, the method comprising: requesting, by a sending terminal, MAC address information of a receiving terminal stored in a UICC of a receiving terminal; In response to transmitting the MAC address information stored in the UICC to the transmitting terminal, and using the obtained MAC address information of the receiving terminal by the Bluetooth module or the WiFi module of the transmitting terminal, the receiving terminal and the socket ( Socket) and the transmitting terminal transmits a large amount of data to the receiving terminal through Bluetooth or WiFi communication.

Meanwhile, before the MAC address request, the transmitting terminal executes one of a process of driving a user screen (UI) or executing an application for transmitting information, selecting a large amount of data to transmit, and specifying a receiving terminal. The above may further include.

Meanwhile, in one embodiment of the present invention, both the transmitting device and the receiving device may be NFC terminals capable of communicating by NFC. In this case, the transmitting device operates in the NFC reader mode and receives the receiving device. Since the terminal is in an idle state, the terminal may be in an NFC card mode.

On the other hand, the above description has been described in the entire process performed by both the transmitting terminal and the receiving terminal, but the individual performing process of the transmitting terminal or the receiving terminal will also be included within the scope of the present invention.

1 shows an overall configuration of a P2P communication system to which the present embodiment is applied.

The P2P communication system 100 according to the present embodiment may be configured to include a transmitting terminal 110 and a receiving terminal 120 of a large amount of data, and the transmitting terminal 110 and the receiving terminal 120 may be Both may be NFC terminals that support NFC.

Hereinafter, although both the transmitting terminal and the receiving terminal of the present embodiment will be described as being an NFC terminal, it is not limited thereto.

The transmitting terminal 110 includes a transmitting UICC or USIM 112, a transmitting NFC module 114, a transmitting Bluetooth module or a WiFi module 116, and includes other user interface modules or application modules. can do.

The receiving terminal 120 may also include a receiving UICC or USIM 122, a receiving NFC module 124, a receiving Bluetooth module or a WiFi module 126 to correspond to the transmitting terminal 110. have.

At this time, the transmitting UICC or USIM 112 stores a large amount of data (for example, a multimedia address book) to be transmitted P2P according to the present embodiment, and the transmitting NFC module 114 operates in the NFC reader mode. Can be.

Meanwhile, the receiving UICC or USIM 122 has a file structure that stores the MAC address information of the receiving terminal, and the MAC address of the receiving terminal is divided into a Bluetooth MAC address or a WiFi MAC address and is UICC. The file format may be stored in the form of an elementary file (EF). The basic file storing the Bluetooth MAC address or the WiFi MAC address may be expressed as EF_BT_MacAddress and EF_WiFi_MacAddress, respectively, and these basic files EF_BT_MacAddress and EF_WiFi_MacAddress may be defined under a predetermined dedicated file (DF).

The file structure of the UICC for EF_BT_MacAddress and EF_WiFi_MacAddress will be described in more detail below.

When the transmitting NFC module 114 is executed in the NFC card mode according to this embodiment, the receiving NFC module 124 in one-step to the receiving NFC module 124 MAC address information of the receiving terminal, more specifically, the receiving Bluetooth module Or request the MAC address information of the WiFi module.

After receiving the request, the receiving NFC module 124 extracts the MAC address information of the receiving Bluetooth module or the WiFi module from the EF_BT_MacAddress or EF_WiFi_MacAddress stored in the receiving UICC 122, and then transmits the received NFC module 114 to the transmitting NFC module 114. Answer

The transmitting NFC module 114 may receive (acquire) MAC address information of the receiving Bluetooth module or the WiFi module from the receiving NFC module and then store the MAC address information in the transmitting UICC 112.

Next, the transmitting side Bluetooth module or the WiFi module 116 transmits a socket request to the receiving side Bluetooth module or the WiFi module 126, and receives the response (ACK). Pairing between the WiFi modules is completed.

After pairing the Bluetooth module or the WiFi module between the two terminals, P2P communication is possible by the transmitting Bluetooth module or the WiFi module 116 transmitting a large amount of data to the receiving Bluetooth module or the WiFi module 126 in a Bluetooth or WiFi manner. Done.

Of course, the transmitting terminal 110 may execute a predetermined application or applet before the MAC address request, thereby selecting a large amount of data to be transmitted or performing P2P communication with a plurality of receiving terminals. In this case, one of them may be designated or a user interface (UI) for securing a receiving terminal may be provided.

More detailed configuration and flow of the transmitting and receiving terminal will be described again with reference to FIG. 5.

Meanwhile, data communication between the UICC and the NFC module in both the transmitting and receiving terminals may use a single wire protocol (SWP) defined in ETSI TS 102.613 and a host controller interface (HCI) defined in TS 102.622.

In addition, the transmitting / receiving terminal may store the Bluetooth MAC address information and the WiFi MAC address information in EF_BT_MacAddress or EF_WiFi_MacAddress, which are predetermined basic files in the UICC file structure, through an ISO 7816 command.

As described above, in the present embodiment, when P2P transmission and reception of a large amount of data such as a multimedia address book between two NFC terminals, the Bluetooth or WiFi MAC address information stored in the UICC of the counterpart terminal is acquired when the NFC session is formed, and thereafter. There is a P2P transmission and reception of large-capacity data through a separate Bluetooth or WiFi, not NFC P2P method.

In the conventional NFC standard, P2P communication is performed between two NFC terminals according to ISO 18092. In this case, the present embodiment is compared with a limited distance between terminals (~ 10cm) and a slow data transmission rate (~ 484Kbps). For example, by using the UICC and NFC technology (NFC reader mode on the transmitting side and NFC card mode on the receiving side) to acquire and connect the Bluetooth or WiFi connection information of the other terminal in a batch, P2P communication is performed by the corresponding communication method. As a result, improvements in distance (~ several meters) and data rates (> 2 Mbps) can be expected.

2 illustrates an example of a UICC application structure applied to the present embodiment.

As shown in FIG. 2, file types stored in the UICC or USIM of the present embodiment may be classified into a master file (MF), a dedicated file (DF), and an elementary file (EF).

MF refers to a unique Mandatory File that contains an Access Condition and may optionally contain DFs and EFs.

A DF is a file that enables functional grouping of a file. The DF may be a parent of DFs and / or EFs, and may be referred to as a file identifier.

Some file identifiers are reserved for specific use, for example, DF _TELECOM is set to '7F10' and DF _GSM is set to '7F20' in the DF. (See Figure 2)

Among these, DF _TELECOM may be optionally used and includes application independent information.

The DF _PHONEBOOK under DF _TELECOM , '7F10', is set to '5F3A' for DF _MULTIMEDIA , '5F3B' for DF _MULTIMEDIA , and '5F50' for DF _GRAPHIC .

On the other hand, EF _DIR is a linear fixed file under MF, which is a kind of application independent file.

In FIG. 2, the file identifier of each DF is also displayed according to the reserved resource.

In such a file structure, the MAC address information and the WiFi MAC address information of the Bluetooth according to the present embodiment may be stored in the form of EF_BT_MacAddress and EF_WiFi_MacAddress, which are basic files, and included in the file structure of the UICC.

More specifically, EF_BT_MacAddress and EF_WiFi_MacAddress may be located under DF _TELECOM (file identifier 7F10) and may have '6F1X' as a file identifier. In 6F1X, which is a file identifier of EF_BT_MacAddress and EF_WiFi_MacAddress, 'X' means one of 0 to F.

However, the file structure of the UICC or USIM according to the present embodiment is not limited to FIG. 2 and may be in another form as long as it stores the MAC address information and the WiFi MAC address information of Bluetooth that can be obtained when the NFC session is connected.

3 is a flowchart showing a file information registration process according to the present embodiment.

The terminal according to the present embodiment includes a UICC or USIM for storing a large amount of data such as a multimedia address book together with a Bluetooth module or a WiFi module.

The registration process of the Bluetooth MAC address information or the WiFi address information in the UICC in the UICC is the same as that of FIG.

When the terminal is in the booting state, after securing the Bluetooth MAC address information or the WiFi address information of the Bluetooth module or the WiFi module included in the terminal (S320), the basic file of the Bluetooth MAC address information or WiFi address information on a certain file structure of the UICC Save in the form (S330)

At this time, the basic file form and structure of the stored Bluetooth MAC address information or WiFi address information are as described with reference to FIG. 2.

That is, in the file information registration process, in the process of exchanging information between the UICC of the terminal and the terminal, for example, the Bluetooth MAC address information or the WiFi address information is obtained by using an ISO 7816 command or the like, and then the specific EF file of the UICC ( EF_BT_MacAddress and EF_WiFi_MacAddress).

This file information registration process may be performed in the NFC module shown in FIG. That is, the NFC module obtains the Bluetooth MAC address information or the WiFi MAC address information from the Bluetooth module or the WiFi module at the time of booting the terminal, and then uses the SWP protocol or the HCI interface, etc., to display the Bluetooth MAC address information or the WiFi MAC address in a predetermined area of the UICC. Information can be stored.

Through this registration process, the Bluetooth MAC address information or WiFi MAC address information stored in the UICC is used for the P2P communication process as described in FIG. 4.

4 shows the overall signal flow of P2P communication according to the present embodiment.

As described in FIG. 1, both the transmitting terminal and the receiving terminal include a Bluetooth module or a WiFi module in addition to the NFC module, and the UICC in which the Bluetooth MAC address information or the WiFi MAC address information is stored through the process shown in FIG. 3. It is assumed to include.

First, the transmitting terminal drives a user interface (UI) for P2P transmission of a large amount of data such as a multimedia address book or executes a P2P transmission application (S410).

In addition, in some cases, a user interface for requesting confirmation of a receiver may be provided to confirm a receiving terminal or to designate one of a plurality of receiving terminals.

Step S410 and the receiver confirmation request process may be implemented using a Java applet (Applet) or a separate application installed in the transmitting terminal, but is not limited thereto. Other NFC modules, UICC, etc. may be performed.

In step S410, when the P2P transmission is started, the NFC module of the transmitting terminal is executed in the NFC reader mode (S420), and then generates a message requesting the receiving terminal to transmit MAC address information to the receiving terminal. Transmit (S430). The MAC address at this time is Bluetooth MAC address information or WiFi MAC address information.

In step S420 and S430, the receiving terminal is used as a server side device in the idle state, that is, Bluetooth or WiFi pairing process, it will be able to operate in the NFC card mode.

The MAC address request message transmitted to the receiving terminal may include an ISO command for obtaining information of EF_BT_MacAddress and EF_WiFi_MacAddress stored in the UICC through a file registration process.

Upon receiving the MAC address request message, the receiving terminal extracts Bluetooth MAC address information or WiFi address information from EF_BT_MacAddress and EF_WiFi_MacAddress stored in its UICC and transmits them to the transmitting terminal (S440).

Next, the transmitting terminal performs the Bluetooth pairing or the WiFi pairing process using the Bluetooth MAC address information or the WiFi address information of the receiving terminal obtained through the S420 to S440 processes (S450).

When the Bluetooth pairing or WiFi pairing process is completed, the transmitting terminal transmits the corresponding large-capacity data (multimedia address book, etc.) to the receiving terminal by using the Bluetooth module or the WiFi module (S460).

On the other hand, the Bluetooth pairing (paring) and WiFi pairing process in step S450 may use a known technique, specifically, the socket request using the MAC address information of the receiving terminal obtained by the transmitting terminal in step S440 Is transmitted to the receiving terminal, and the receiving terminal may be performed by transmitting an ACK or an Accept message as a response thereto.

In more detail, APIs or classes such as BluetoothSocket and BluetoothServerSocket may be used, and one terminal becomes a server socket using a BluetoothServerSocket, and another terminal remotely connects to a terminal having this server socket. connect) request. In this connection request, the MAC address of the terminal having the server socket is used. The terminal receiving the connection request completes the Bluetooth pairing by accepting (accepting or ACKing) the connection requested by the client terminal using the BluetoothSocket.

That is, according to the present embodiment, when the receiving terminal becomes the server side terminal and opens the server socket, and the transmitting terminal makes a connection request using the MAC address information of the receiving terminal, the receiving terminal accepts it ( ACK) to perform pairing.

In addition, since the WiFi pairing process may be performed similarly to the above-described Bluetooth pairing process, a detailed description thereof will be omitted.

5 is a block diagram of detailed functional block diagrams and data flows of a transmitting and receiving terminal apparatus according to an embodiment of the present invention.

5 corresponds to an embodiment of P2P transmission / reception of multimedia address book information (or address book) stored in the UICC.

Similar to FIG. 1, the transmitting terminal 500 and the receiving terminal 600 are both application modules 510 and 610 that provide address book information, NFC modules 520 and 620, and address book information of each terminal. And UICCs 530 and 630 storing EF_MACAddress, which is a basic file including MAC address information, and Bluetooth / WiFi modules 540 and 640.

Looking at the signal processing and data flow in such a configuration, first, when a user executes an address book transmission application or a user interface program therefor in the application module of the sending terminal, the application module 510 receives the NFC module 520 from the receiving side. Request the MAC address information of the terminal (① process).

The receiving NFC module 520 receiving the request is executed in the NFC reader mode and transmits a MAC address request message to the receiving NFC module 620. (Step 2) At this time, the receiving NFC module 620 is NFC. Run in card mode.

The receiving NFC module 620 requests and receives its MAC address information (ie, Bluetooth / WiFi address information) from the receiving UICC 630 (steps 3 and 4), and sends it to the transmitting NFC module 520. Return (⑤ process).

The transmitting NFC module 520 transmits the received Bluetooth / WiFi address information of the receiving terminal to the application module 510 (step ⑥), and the application module transmits the Bluetooth / WiFi address information of the corresponding receiving terminal to the Bluetooth / WiFi. Transfer to module 540 (Step ⑦).

The Bluetooth / WiFi module 540 of the transmitting terminal requests a Bluetooth / WiFi connection to the receiving terminal using the MAC address information of the receiving terminal to form a Bluetooth / WiFi pairing. )

In this state, when the application module 510 of the transmitting terminal receives its address book information from the UICC 530 (step S), and transmits it to the Bluetooth / WiFi module 540 (step S), The Bluetooth / WiFi module 540 transmits the corresponding address book information to the Bluetooth / WiFi module of the receiving terminal P2P.

According to the embodiments of the present invention as described above, as a form of contactless service of the UICC, P2P transmission of a large amount of data such as a multimedia address book (address book) can be performed through Bluetooth or WiFi.

To this end, the UICC has to store the Bluetooth MAC address information or the WiFi MAC address information of the terminal in the form of a basic file, and this file registration process may be performed at booting of the terminal.

In addition, by acquiring Bluetooth MAC address information or WiFi address information stored in the UICC of the counterpart terminal through the NFC session, and performing Bluetooth / WiFi pairing using the MAC address information, a large amount of data can be obtained using the Bluetooth or WiFi method. P2P can be sent quickly.

Thus, the MAC address of the other terminal can be obtained in one step quickly in the NFC mode with short session setup time, and P2P transmission and reception of actual data can be efficiently performed by using another communication method (Bluetooth / WiFi) that has a high transmission speed. It is effective.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. In other words, within the scope of the present invention, all of the components may be selectively operated in combination with one or more. In addition, although all of the components may be implemented as one independent hardware, some or all of the components may be selectively combined to perform a part or all of the functions in one or a plurality of hardware. As shown in FIG. Codes and code segments constituting the computer program may be easily inferred by those skilled in the art. Such a computer program may be stored in a computer readable storage medium and read and executed by a computer, thereby implementing embodiments of the present invention. As the storage medium of the computer program, a magnetic recording medium, an optical recording medium, a carrier wave medium, or the like may be included.

It is also to be understood that the terms such as " comprises, "" comprising," or "having ", as used herein, mean that a component can be implanted unless specifically stated to the contrary. But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims (11)

In a terminal device including a UICC (Universal Integrated Circuit Card),
The contactless front end interface (CLF) or the CLFI protocol (CLFIIP) of the terminal device supports peer-to-peer mode communication using WiFi or Bluetooth with a file stored in the UICC. Terminal device. Bluetooth module or WiFi module;
A Universal Integrated Circuit Card (UICC) for storing the MAC (Media Access Control) address information of the Bluetooth or the MAC address information of WiFi;
Terminal device comprising a. The method of claim 2,
The terminal device, upon booting, stores the MAC (Media Access Control) address information of the Bluetooth or the MAC address information of the WiFi in the form of an elementary file (EF) on the file structure of the UICC. The method of claim 3,
And the basic file is stored under DF _TELECOM in the UICC file structure. 5. The method of claim 4,
Wherein the file identifier of the DF _TELECOM is 7F10 and the file identifier of the basic file including the MAC (media access control) address information of the Bluetooth or the MAC address information of WiFi is 6F1X. The method of claim 2,
The terminal device is an NFC-enabled terminal device including a NFC (Near Field Communication) module,
The terminal device is characterized in that the terminal device generates and transmits a MAC address request message requesting to transmit MAC address information of Bluetooth or MAC address information of WiFi to the other terminal device for P2P transmission when the NFC mode is executed. The method according to claim 6,
The terminal device receives the MAC address information of Bluetooth of the opposite terminal device or MAC address information of WiFi as a response to the MAC address request message,
And performing peer-to-peer transmission after completing Bluetooth pairing or WiFi paying with the counterpart terminal by using the MAC address information of the counterpart terminal or the MAC address information of WiFi. A file registration method of a terminal device including a Bluetooth module or a WiFi module and a Universal Integrated Circuit Card (UICC),
When the terminal device is in a booting state, acquiring Bluetooth MAC address information or WiFi address information of the Bluetooth module or the WiFi module;
Storing the Bluetooth MAC address information or WiFi address information in a basic file format on the file structure of the UICC;
File registration method comprising a. A P2P transmission method of a terminal device including a Bluetooth module or a WiFi module, a NFC (Near Field Communication) module, P2P transmission information, and a Bluetooth Integrated Circuit Card (UICC) for storing the Bluetooth MAC address information or WiFi address information. ,
Generating and transmitting a MAC address request message requesting the counterpart terminal device to transmit MAC address information of Bluetooth or MAC address information of WiFi when the NFC mode is executed;
Receiving MAC address information of Bluetooth of the opposite terminal device or MAC address information of WiFi as a response to the MAC address request message;
Performing P2P transmission after completing Bluetooth pairing or WiFi paying with the counterpart terminal by using the MAC address information of the counterpart terminal or the MAC address information of WiFi;
P2P transmission method comprising a. 10. The method of claim 9,
The terminal device further comprises the step of providing at least one of a user interface for selecting the information for the P2P transmission and a user interface for identifying the counterpart terminal device. 10. The method of claim 9,
The terminal device operates in the NFC reader mode, the counterpart terminal device is characterized in that the P2P transmission method operating in the NFC card mode.

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