KR101777043B1 - Method for Generating Electronic Signature based on Asynchronous Local Area Radio Communication - Google Patents

Abstract

The present invention relates to a method for generating an electronic signature based on asynchronous local area radio communications, the method performed through a chip of a low power medium having a button installed on at least one side and comprising the following steps: storing authentication information for identifying and authenticating a predetermined terminal; transmitting a wireless signal, which does not specify a reception side, based on manipulation of the button on the one side; waiting and receiving the asynchronous signature generation information; maintaining a session ID of the asynchronous signature generation information for identifying asynchronous communications with an m terminal and initiating an electronic signature value while maintaining the session ID; receiving, from the m terminal, asynchronous signature request information which includes the session ID and requests providing of an electronic signature value generated based on the asynchronous signature generation information; transmitting an asynchronous wireless signal, corresponding to specified asynchronous response information, when the electronic signature value is not generated; and transmitting an asynchronous wireless signal, corresponding to asynchronous signature information including the session ID and the electronic signature value, to the m terminal when the electronic signature value is generated. According to the present invention, provided is the electronic signature based on asynchronous local area radio communications, the electronic signature which is safe to an attempt for hacking such as force attack.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an asynchronous short-

The present invention relates to a method of executing through a chip of a low-power medium having built-in one or more chips having an asynchronous short-range wireless communication function and a certificate-based electronic signature function and having buttons on at least one side thereof, (M > = 1) terminals that have received the transmitted radio signal, receive a connection request from the M (M > = 1) terminals that received the transmitted radio signal, (1 ≤ m ≤ M) terminals among the M terminals requested to be accessed by using the authentication information to confirm the connection, and to identify asynchronous communication with the access- An asynchronous document containing specified information, including the certificate PIN and signature target information, required for ID and certificate-based signature generation. Receiving the generated information, receiving the generated information, and maintaining the session ID of the asynchronous signature generation information for identifying the asynchronous communication with the m th terminal for a predetermined time, and generating a digital signature value while maintaining the session ID From the mth terminal, asynchronous signature request information including the session ID and requesting the provision of the digital signature value generated based on the asynchronous signature generation information, and receiving the asynchronous signature request information from the mth terminal The asynchronous radio signal corresponding to the specified asynchronous response information if the digital signature value is not generated at the time of reception, and when the digital signature value is generated at the time of receiving the asynchronous signature request information from the mth terminal To the m < th > terminal, an asynchronous radio signal corresponding to the asynchronous signature information including the session ID and the digital signature value Wherein the digital signature value is not provided in response to the asynchronous signature generation information, and when the asynchronous signature generation information is N (N> n) bits exceeding a designated size n (n≥160) bits, The m-th terminal divides the N-bit asynchronous signature generation information into k (k? (Ni)) bit unit data capable of containing the sequence ID of i (i? 1) t > = 2) bit streams and simultaneously transmitting t bitstreams sequentially assigned sequence IDs to each bitstream, asynchronously, and the communication chip asynchronously receives t bitstreams, And restoring N-bit asynchronous signature generation information by combining each k-bit unit data included in the received t bitstreams.

An electronic signature service has been proposed in which a digital signature is generated in a signature providing device based on a local communication (e.g., NFC, etc.) between the terminal and the signature providing device and is provided to the terminal (see Patent Document 10-2015-0094110 .19)).

Meanwhile, the conventional NFC of the short-range communication-based digital signature service has a request / response structure in which a signal transmitted from one side is received by another side, the information is processed, and the result is returned. For example, if the terminal device provides a command for requesting a digital signature via NFC to a signature providing device, the signature providing device responds to the generated digital signature, or if the digital signature fails, Response structure. Of course, most short-range communications that provide half-duplex or full-duplex communication as well as NFC are intended to operate as a request / response structure. This is because the request / response structure based communication is intuitive. However, the intuitiveness of this request / response structure can be destroyed by hacking attempts such as various assignment attacks (for example, an attack that identifies internal actions by analyzing which responses are received when a request is entered). In particular, when a signature providing device that responds to a request in a conventional short-range communication-based digital signature service is implemented in a card form, a relatively low-level security (for example, Key security), but according to Wikipedia, there is a case in which about 56 bits of DES was destroyed in about a day in 1999. If the current level of technology can be destroyed without taking less than an hour.

An object of the present invention to overcome the above-mentioned problems is to provide a wireless communication device which is implemented through a chip of a low-power medium having one or more chips having an asynchronous local wireless communication function and a certificate- The method includes a first step of storing authentication information for identifying and authenticating a predetermined terminal, a second step of transmitting a radio signal that does not specify a receiving side based on the button operation of the one side, A third step of receiving a connection request from the received M (M? 1) terminals, and a third step of identifying and authenticating a predetermined m (1? M? M) terminal among the M terminals requested to access using the authentication information, A session ID for identifying asynchronous communication with the access authorized m terminal, and a certificate P Receiving asynchronous signature generation information including specified information including IN and signature target information in a specified information structure and receiving the asynchronous signature generation information in response to a session of the asynchronous signature generation information to identify asynchronous communication with the m & A step of generating a digital signature value while maintaining the ID for a certain period of time and maintaining the session ID; and a sixth step of generating a digital signature including the session ID and based on the asynchronous signature generation information, A step of receiving asynchronous signature request information requesting the provision of the asynchronous signature request information from the mth terminal when the asynchronous signature request information is received from the mth terminal; And when the asynchronous signature request information is received from the m < th > terminal, the digital signature And sending an asynchronous radio signal corresponding to the asynchronous signature information including the session ID and the digital signature value to the mth terminal when the generated asynchronous signature information is generated, (N > n) bits, where the asynchronous signature generation information is greater than a designated size n (n > = 160) (t > = 2) bit streams including k-bit unit data, and generates bit streams (k < Asynchronously transmitting t bit streams obtained by sequentially assigning sequence IDs to the received bit streams, and the communication chip asynchronously receives t bitstreams and then transmits k bit unit data And N An asynchronous short-range wireless communication based on the digital signature implemented method for restoring the asynchronous signature generation information in the tree to provide.

A method for implementing an asynchronous local area wireless communication based digital signature according to the present invention includes executing at least one chip having an asynchronous local area wireless communication function and a certificate based electronic signature function and executing through a chip of a low power medium A first step of storing authentication information for identifying and authenticating a predetermined terminal and a second step of transmitting a radio signal not specifying a receiving side based on the button operation of the one side, (M > = 1) terminals receiving the authentication request, and a third step of identifying and authenticating a predetermined m (1? M? M) terminal among the M terminals requested to access using the authentication information A fourth step of accepting the connection and a session ID for identifying asynchronous communication with the access authorized m < th > A fifth step of receiving and receiving asynchronous signature generation information including specified information including a required certificate PIN and signature target information in a specified information structure; and a fifth step of receiving asynchronous signature generation information including asynchronous signature generation information A session ID of the session ID is generated for a predetermined period of time, and a session ID is generated while maintaining the session ID; A step of receiving asynchronous signature request information requesting the provision of an electronic signature value; and a seventh step of receiving asynchronous signature request information from the mth terminal, At the time of receiving the asynchronous signature request information from the m < th > And transmitting the asynchronous radio signal corresponding to the asynchronous signature information including the session ID and the digital signature value to the mth terminal when the digital signature value is generated, Wherein if the asynchronous signature generation information is N (N > n) bits exceeding a designated size n (n > = 160) bits, the m < th > Information is divided into k (k? (Ni)) bit unit data capable of containing the sequence ID of i (i? 1) bits, and t (t? 2) bit streams including k- The asynchronous transmission of t bit streams sequentially assigning sequence IDs to each bit stream, and the communication chip asynchronously receives t bit streams and then transmits the t bit streams k-bit unit data To recover N-bit asynchronous signature generation information.

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According to the present invention, the connection request may include an authentication value capable of authenticating a terminal installed with a specific application using the authentication information.

According to the present invention, the first step may further include storing a key value for asynchronous secure communication with a predetermined terminal, wherein the asynchronous signature generation information is decryptably received through the key value, Lt; / RTI >

According to the present invention, the asynchronous signature generation information may include an APDU (Application Protocol Data Unit) command structure for the IC chip when the chip includes an IC chip.

According to the present invention, the chip checks a first (1 < = l < th >) th bit stream that is not effectively received among the t bit streams to be received, And may receive the first bitstream by transmitting stream request information requesting the first bitstream or the entire bitstream not including the session ID to the mth terminal. Meanwhile, the m < th > terminal repeatedly transmits the t bitstreams more than a predetermined number of times, and the chip identifies the first (1 < , And if the first bitstream that has not been received successfully is identified, the first bitstream can be effectively received in the course of receiving the next bitstream. On the other hand, the k-bit unit data may include a session ID of j (j? 1) bits.

According to the present invention, the low power medium may include a chip integrated with the asynchronous local wireless communication function and the certificate based electronic signature function.

According to the present invention, the low power medium includes a first chip having an asynchronous local wireless communication function and a second chip having a certificate based electronic signature function, wherein the first chip is connected to the second chip Lt; / RTI > On the other hand, when the second chip includes an IC chip, the first chip receives asynchronous signature generation information including an APDU command structure from the mth terminal, injects an APDU command into the IC chip, Or initiate a procedure for generating an electronic signature value by injecting the APDU command into the IC chip based on the asynchronous signature generation information received from the mth terminal.

According to the present invention, the m < th > terminal waits for a certain period of time to generate an electronic signature value from a chip of the low-power medium after transmitting a wireless signal including the asynchronous signature generation information, It is possible to transmit a radio signal.

According to the present invention, the first step may further include storing a key value for asynchronous secure communication with a predetermined terminal, wherein the asynchronous signature information is decrypted through the m < th >Lt; / RTI >

According to the present invention, the asynchronous signature information may include an APDU response structure for the IC chip when the chip includes the IC chip.

According to the present invention, when the asynchronous signature information is N (N> n) bits exceeding a designated size n (n? 160) bits, the chip transmits the N-bit asynchronous signature information to i (T? 2) number of bit streams including k-bit unit data, and a sequence number ID is assigned to each bit stream. Asynchronously transmits t bit streams sequentially assigned, and the m < th > terminal asynchronously receives t bit streams and combines k bit unit data included in the received t bit streams on the basis of the sequence ID N-bit asynchronous signature information can be restored. Meanwhile, the m < th > terminal identifies a first (1 < = l < th >) th bit stream that is not effectively received among the t bit streams to be received, The first bitstream may be received by transmitting the stream request information requesting the first bitstream or the entire bitstream not including the session ID to the chip of the medium. On the other hand, the chip repeatedly transmits the t bitstreams more than a designated number of times, and the mth terminal checks a first (1 < = l < , And if the first bitstream that has not been received successfully is identified, the first bitstream can be effectively received in the course of receiving the next bitstream.

According to another aspect of the present invention, there is provided an asynchronous local area network (WLAN) -based digital signature realization method, comprising: storing a session ID for identifying asynchronous communication with an access terminal And erasing the session ID for the m < th > terminal if an asynchronous radio signal is not received.

According to the present invention, a digital signature is generated from a chip of a low-power medium according to a request of a terminal and is provided to a terminal, and a request from one side is received by the other side to perform a requested operation, It is advantageous to provide an asynchronous short distance wireless communication based digital signature for a hacking attempt such as an attack of a connection by implementing a short distance wireless communication between a terminal and a chip of a low power medium based on an asynchronous short distance wireless communication which exchanges signals.

According to the present invention, a chip of a low-power medium operating in a server mode (or a master mode) is confirmed through asynchronous short-range wireless communication in a terminal without touching a low-power medium within 1 cm by locating an NFC chip position of the terminal like a conventional NFC There is an advantage in that it is requested to generate a digital signature and receive an electronic signature generated from a chip of a low-power medium and use it in an authentication procedure.

1 is a diagram illustrating a configuration of a low-power medium for signing using a certificate based on asynchronous short-range wireless communication according to an embodiment of the present invention.
2 is a diagram illustrating a functional configuration of a terminal according to an embodiment of the present invention.
3 is a diagram illustrating a process of connecting to a communication chip of a low-power medium through asynchronous short-range wireless communication in a terminal according to an embodiment of the present invention.
4 is a diagram illustrating a process of requesting a terminal to generate a signature from a low-power medium through asynchronous short-range wireless communication according to an embodiment of the present invention.
5 is a diagram illustrating a process of generating an electronic signature value based on asynchronous short-range wireless communication in a low-power medium according to an embodiment of the present invention.
6 is a diagram illustrating a process of requesting an electronic signature value from a low-power medium through asynchronous short-range wireless communication in a terminal according to an embodiment of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

In other words, the following embodiments correspond to the preferred embodiment of the preferred embodiment of the present invention. In the following embodiments, a specific configuration (or step) is omitted, or a specific configuration (or step) (Or steps), or an embodiment that incorporates functions implemented in more than one configuration (or step) into any one configuration (or step), a particular configuration (or step) It will be apparent that the present invention is not limited to the embodiments described below.

In the following description 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 invention rather unclear. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, intention or custom of the operator. Therefore, the definition should be based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs Only.

1 is a diagram illustrating a configuration of a low-power medium for signing using a certificate based on asynchronous short-range wireless communication according to an embodiment of the present invention.

1 is a block diagram illustrating a wireless communication system according to an exemplary embodiment of the present invention. Referring to FIG. 1, when a wireless signal is transmitted and received between a chip of a low-power medium located in a short distance and a terminal 200, And generates an electronic signature value in a chip of a low-power medium based on an asynchronous short-range wireless communication structure in which wireless signals are exchanged irrespective of the completion of the operation, and provides the digital signature value to the terminal 200 Those skilled in the art will be able to refer and / or modify Figure 1 to illustrate various implementations of the low power medium configuration (e.g., some of the components may be omitted, or broken down, The present invention encompasses all of the above-described methods of practicing the invention, Only the exemplary method is not limited that the technical features.

Unlike the synchronous communication structure in which a wireless signal is transmitted and received in a short distance (for example, within a maximum of 100 m) and communication is performed, a wireless signal transmitted from one side is received at another side, information processing is performed, Asynchronous short range wireless communication is defined as a communication structure in which the other party receives the wireless signal transmitted from the other party and the information processing and the result response can be processed asynchronously. For example, the present invention is characterized in that a short-range wireless communication including a request / response structure such as a pairing-based short-range wireless communication scheme or an NFC (Near Field Communication) scheme is defined as a synchronous short-range wireless communication, It can be defined as wireless communication. Currently, most short-range wireless communication is synchronous short-range wireless communication. In this case, since a specified operation is performed for a certain request of one side and the result is responded, it is vulnerable to hacking such as various assignment attacks. For example, in the case of synchronous short-range wireless communication, when one side requests a signature generation while providing a specific value, the other side responds to the generated digital signature value after generating the digital signature value. In this case, It is possible to determine which signature value will be generated when a certain value is input by analyzing the signature value that is responded to by providing a specific value in a state where the algorithm is known. However, in the case of NFC, it is possible to limit the communication range to a maximum of 10 cm, which makes it difficult to attempt such a hacking. However, in the case of the synchronous short range wireless communication having a communication range of up to 100 m, it is inevitably vulnerable to various assignment attacks within the available communication range.

The low-power medium and the terminal 200 according to the present invention are characterized in that they communicate with each other by transmitting and receiving wireless signals in a short distance and communicating using an asynchronous short-range wireless communication structure.

The low-power medium of the present invention includes at least one chip having at least one chip having an asynchronous short-range wireless communication function and a certificate-based electronic signature function and having at least one button mounted thereon. The medium is preferably a nonconductive upper medium made of a resin material, Wherein one or more chips having an asynchronous local wireless communication function and a certificate based electronic signature function are embedded between the upper medium and the lower medium and the buttons are mounted on one side of the low power medium do. In the present invention, a medium having an asynchronous local wireless communication function and a certificate-based electronic signature function is not limited to a low-power medium, but may be implemented in various forms (for example, rectangular parallelepiped shape, UBS memory shape, etc.) It is clear that the present invention is in the scope of the present invention, and that various media besides the form of a low power medium belong to the scope of the present invention.

According to the first embodiment of the present invention, the low-power medium includes a communication chip 105 (or a first chip) having an asynchronous local wireless communication function and an IC (Integrated Circuit) chip And the communication chip 105 and the IC chip 150 (for example, a chip according to the IC card standard) can communicate with each other in the low power medium. For example, the communication chip 105 may operate as a reader for the IC chip 150 in a low-power medium and communicate with the IC chip 150 based on a half-duplex communication structure.

According to a second embodiment of the present invention, the low-power medium may include a chip including an asynchronous local wireless communication function and a certificate-based electronic signature function. In this case, the communication chip 105, The IC chip 150 may be implemented as one integrated chip. Hereinafter, the characteristics of the present invention will be described based on an embodiment in which the communication chip 105 and the IC chip 150 are mounted in a low-power medium according to the first embodiment, but the present invention is not limited thereto The communication chip 105 and the IC chip 150 may be implemented in a single chip form, and the present invention clearly encompasses such an implementation method as well.

1, the low-power medium includes a communication chip 105 having an asynchronous short-range wireless communication function and an IC chip 150 having a certificate-based digital signature function. A button unit 180 equipped with a possible button and a battery 185 for supplying operation power to the communication chip 105 and / or the IC chip 150 may be incorporated. On the other hand, according to an embodiment of the present invention, a COB (Chip On Board) (not shown) for implementing a contact interface for the IC chip 150 may be mounted on one side of the low power medium, And is electrically connected to the IC chip 150.

The low power medium includes a button unit 180 having one or more buttons that can be operated by a user. The button unit 180 is connected to the communication chip 105 to perform a user operation on the communication chip 105 ). Preferably, the button unit 180 may include one button for on / off function, and a plurality of buttons for performing numeric input, confirmation / cancellation, and / or on / The present invention is not limited thereto.

According to the embodiment of the present invention, the communication chip 105 requests M (M? 1) terminals 200 to connect via an asynchronous radio signal, and transmits the M terminals 200), and operates in a server mode (or a master mode) for maintaining and managing a session with the access authorized m terminal 200 In this case, the m th terminal 200 may operate in a client mode (or a slave mode) in which it connects to the communication chip 105 operating in the server mode (or master mode). While the communication structure between a normal terminal and a card is a half-duplex communication structure (for example, a structure in which only a command is responded to a command from a card when commanded from the terminal), the terminal 200 and the low power medium of the present invention perform asynchronous short- Is a server mode (or a master mode). This is one of the differences from the communication structure between the terminal and the card operating in the conventional half-duplex communication structure. That is, by allowing the communication chip 105 of the low-power medium to operate in the server mode (or the master mode) for the terminal 200, a terminal possessed by an arbitrary attacker can access the low- It is possible to block the communication chip 105 from accessing the IC chip 150 as well as to block the communication.

1, the communication chip 105 of the low-power medium includes an asynchronous radio processing unit 110 that performs an operation for transmitting and receiving an asynchronous radio signal with an external terminal 200, and the communication chip 105 And a memory unit 125 for storing information necessary for the operation of the communication chip 105. The communication unit 105 is connected to the communication chip 105 via the communication chip 105, And an interface unit (120) for interfacing communication with the IC chip (150) in the low power medium when the IC chip (150) is provided.

The asynchronous radio processing unit 110 transmits an asynchronous radio signal that does not specify a receiving side through an antenna or receives an asynchronous radio signal transmitted from a terminal 200 in a short range wireless communication range through an antenna, Perform an operation for transmitting an asynchronous radio signal to the terminal 200 in the short-range wireless communication range, and preferably perform a modulation and / or demodulation operation on the asynchronous radio signal in the designated frequency band.

The control unit 115 is a general term for controlling the operation of the communication chip 105. The control unit 115 includes at least one processor and an execution memory, BUS). According to the present invention, the control unit 115 loads at least one program code provided in the communication chip 105 into the execution memory through the processor, and outputs the result through at least one configuration And controls the operation of the communication chip 105. FIG. Hereinafter, a functional structure implemented in the form of a program code and / or a control circuit on the communication chip 105 is shown in the control unit 115 for convenience.

The memory unit 125 is a generic name of a nonvolatile memory corresponding to a storage resource of the communication chip 105 and includes at least one program code executed through the control unit 115 and at least one Save and maintain the dataset. The memory unit 125 basically includes a system program code and a system data set corresponding to the operating system of the communication chip 105, a communication program code and a communication data set for processing a wireless communication connection of the communication chip 105, One application program code and application data set are stored, and the program code and data set corresponding to the functional configuration of the present invention are also stored in the memory unit 125. [

The interface unit 120 is a general term for a configuration for processing low-power medium internal communication between the communication chip 105 and the IC chip 150. The interface unit 120 preferably includes the IC chip 150 ) And half-duplex communication. According to the method of the present invention, the interface unit 120 of the communication chip 105 may operate as a low power medium reader in the presence of the IC chip 150.

The control unit 115 may be connected to a button unit 180 provided on one side of the low power medium and may be operated by the user through the button unit 180. For example, And controls the operation of the asynchronous radio processing unit 110 to transmit the asynchronous radio signal that does not specify the receiving side through the antenna, and controls the asynchronous radio signal transmitted from the terminal 200 in the short- Signal to the terminal 200 in the short-range wireless communication range through the antenna, or to transmit the asynchronous radio signal to the terminal 200 in the short-range wireless communication range through the antenna. That is, according to the present invention, the asynchronous radio signal is transmitted from the communication chip 105 of the low-power medium only through the button operation, so that arbitrary attackers existing within the short-range wireless communication range can be prevented from arbitrarily hacking attempts such as assignment attack.

Referring to FIG. 1, the communication chip 105 of the low-power medium includes an information storage unit 130 for storing authentication information for identifying and authenticating a predetermined specific terminal 200, A signal transmitting unit 132 for transmitting an asynchronous radio signal that does not specify a receiving side based on a user operation on the button unit 180, and M (M > = 1) terminals receiving the transmitted asynchronous radio signal (1? M? M) terminal 200 among the M terminals 200 requested to access the terminal 200 using the authentication information, And a session management unit 138 for managing a session for asynchronous short-range wireless communication with the m-th terminal 200 that has been approved for connection.

According to the first information storage method for communication according to the present invention, the information storage unit 130 stores a specific terminal 200 (for example, a predetermined application previously designated) at the time of manufacturing the low power medium (or the communication chip 105) (E.g., the terminal 200 in which the terminal 225 is installed) and stores the authentication information in the designated storage area of the memory unit 125. [ Meanwhile, the information storage unit 130 may store a key value (for example, an encryption key) for asynchronous secure communication based on the encryption / decryption based on the specific terminal 200 designated at the time of manufacturing the low-power medium (or the communication chip 105) Decryption key of a symmetric key infrastructure, or an encryption / decryption key of a public key infrastructure, etc.) in a designated storage area of the memory unit 125. [

According to the second communication information storing embodiment of the present invention, the communication chip 105 can be manufactured / supplied in a state in which the authentication information and / or the key value are not stored in the designated storage area The button unit 180 of the low power medium may include a plurality of buttons including a plurality of numeric key buttons and at least one function key button. In this case, the information storage unit 130 activates an information registration mode for receiving authentication information based on a function key input through the button unit 180 or a designated number key combination, and in the information registration mode, Authentication information for identifying and authenticating a specific terminal 200 previously designated through the numeric keypad of the controller 180 may be received and stored in a designated storage area of the memory 125. [ Meanwhile, after the authentication information is stored in the designated storage area, a key value for asynchronous secure communication with the specific terminal 200 is inputted through the numeric key button and / or a specific terminal 200 corresponding to the authentication information is designated (E.g., an asynchronous radio signal in which the signal strength is reduced to be within a range of 1 m to 5 m), and stores the key value for the asynchronous secure communication with the specific terminal 200 in a designated storage area have.

According to the third communication information storage embodiment of the present invention, the communication chip 105 can be manufactured / supplied in a state in which the authentication information and / or the key value is not stored in the designated storage area In this case, the information storage unit 130 determines whether or not effective authentication information is stored in a designated storage area of the memory unit 125 based on a function key input through the button unit 180 (for example, NULL values or default values are stored). If valid authentication information is not stored in the designated storage area, the information storage unit 130 activates an information registration mode for registering authentication information, and transmits the asynchronous radio signal (for example, And an asynchronous radio signal in which the signal strength is reduced to be within a range of 1 m to 5 m) and stores authentication information for identifying and authenticating the specific terminal 200 in the designated storage area. In this case, the information storage unit 130 may store the key value for the asynchronous secure communication with the specific terminal 200 corresponding to the authentication information simultaneously with (or after) the registration of the authentication information, and store the key value in the designated storage area .

According to the fourth communication information storage embodiment of the present invention, the communication chip 105 can be manufactured / supplied in a state in which authentication information and / or key values are not stored in a designated storage area And a COB that provides a contact interface between the IC chip 150 and the contact IC reader on one side of the low power medium. In this case, the IC chip 150 receives the authentication information for identifying and authenticating the specific terminal 200 from the terminal having the IC reader via the COB, and stores (or stores) the authentication information in the memory unit 160 of the IC chip 150 Temporary storage). The information storage unit 130 determines whether valid authentication information is stored in a designated storage area of the memory unit 125 based on a function key input through the button unit 180 Is stored). If valid authentication information is not stored in the designated storage area, the information storage unit 130 requests authentication information from the IC chip 150 and transmits the authentication information to the memory unit (not shown) of the IC chip 150 The authentication information may be provided to the specific terminal 200 stored (or temporarily stored) in the IC chip 160. If valid authentication information is provided from the IC chip 150, the authentication information may be stored in the designated storage area . Meanwhile, the IC chip 150 can store (or temporarily store) a key value for asynchronous secure communication with a specific terminal 200 through the COB according to an embodiment of the present invention. The IC chip 150 may request and store the key value and store the key value in a designated storage area.

According to the fifth communication information storage embodiment of the present invention, the information storage unit 130 may store at least one of the first, second, and third communication information storage embodiments according to a method of at least partially combining at least two embodiments of the first, 200, and stores the acquired authentication information in a designated storage area of the memory unit 125 and / or obtains a key value for asynchronous secure communication with the specific terminal 200, ), And thus the present invention is not limited thereto.

According to an embodiment of the present invention, the m th terminal 200 (or a designated server) provides an encryption key corresponding to a key value to be used for decryption in the communication chip 105 according to a designated key distribution procedure, And / or a decryption key corresponding to a key value to be used for encryption in the communication chip 105 may be provided according to a predefined key distribution procedure, and registered and stored in a designated storage medium.

When a button for transmitting an asynchronous radio signal that does not specify a receiving side is input through the button unit 180 provided on one surface of the low power medium, the signal transmitting unit 132 transmits the asynchronous radio signal to the button unit 180 And controls the asynchronous radio processing unit 110 to transmit an asynchronous radio signal that does not specify a receiving side based on a user operation on the asynchronous radio processing unit 110. [ Preferably, the asynchronous radio signal that does not specify the receiver side may include unique ID information assigned to the communication chip 105 (e.g., stored in a designated storage area of the memory unit 125).

According to an embodiment of the present invention, an asynchronous radio signal that does not specify the receiving side can be received by a plurality of terminals existing within a designated short range wireless communication range, and M ) Terminals 200 can transmit an asynchronous radio signal requesting a radio connection to the communication chip 105 in response to an asynchronous radio signal transmitted without specifying a receiving side in the communication chip 105, A predetermined m-th terminal 200 (for example, a terminal 200 that has installed a specific application 225) among the M terminals 200 is connected to the memory unit 125 Corresponding to connection request information including an authentication value that can be authenticated (e.g., by comparison authentication or deriving a specified value through a specified verification operation) via authentication information stored in a designated storage area of the asynchronous radio It can transmit a call. That is, in a normal client-server network connection process, a client inputs an address of a server and connects to the server. On the other hand, when the communication chip 105 of the low-power medium transmits a wireless signal that does not specify a receiver, The difference is that the terminal 200 within a short-range communication range transmits an asynchronous radio signal and connects to the communication chip 105 of a low-power medium, which is different from a normal client-server network connection procedure. Hereinafter, it will be apparent that the operation performed with the mth terminal 200 as its main body is executed through the application 225 installed in the mth terminal 200, without further mention.

The signal receiving unit 134 transmits the asynchronous radio signal transmitted for the connection request from the M (M? 1) terminals 200, and transmits the information read from the asynchronous radio signal for the connection request to the access acknowledgment unit 136).

The connection acknowledgment unit 136 receives a connection request from a predetermined specific m terminal 200 among the M terminals 200 requested to access using the authentication information stored in the designated storage area through the information storage unit 130 And authenticates a connection request of the identified m th terminal (200).

According to an embodiment of the present invention, the m th terminal 200 may repeatedly transmit an asynchronous radio signal including connection request information for the connection request a predetermined number of times, and the signal receiving unit 134 may transmit the asynchronous radio signal including the m It is possible to repeatedly receive the asynchronous radio signal repeatedly transmitted from the terminal 200. In this case, the connection admission unit 136 repeats the process of identifying and authenticating the m th terminal 200 through the authentication information with respect to the access request information repeatedly received from the m th terminal 200 and / only one identification authentication can be performed on the asynchronous radio signal repeatedly transmitted from the m terminal 200. Meanwhile, the m-th terminal 200 may transmit the asynchronous radio signal including the encrypted information after encrypting the connection request information with the designated encryption key. In this case, the connection approval unit 136 may use the key value And decrypt the encrypted connection request information. Meanwhile, the m-th terminal 200 may divide the connection request information into a predetermined number of bit streams and sequentially transmit the connection request information according to the embodiment. In this case, the connection acceptor 136 combines the divided and received bit streams And may restore the connection request information.

According to an embodiment of the present invention, it is preferable that the connection acknowledgment unit 136 does not respond to an approval result even if a connection request to the m th terminal 200 is granted on an asynchronous local area wireless communication structure, The signal transmitting unit 132 may process a simple ACK response (or an ACK response may be omitted) for the connection request, or a radio signal that does not specify the receiving side to be transmitted. Meanwhile, according to another embodiment of the present invention, the connection acknowledgment unit 136 notifies the specific application 225 of the m th terminal 200 to a radio signal transmitted from the signal transmission unit 132 without specifying the reception side, It is possible to process such that only a recognizable access acknowledgment code is included and transmitted, and thus the present invention is not limited thereto. That is, according to the present invention, when M terminals 200 request a connection to a communication chip 105 of a low-power medium, any one of the M terminals 200 can not confirm whether or not their own connection has been approved, Only a predetermined specific m th terminal 200 can recognize whether or not its own connection has been approved. As a result, it is possible to protect the asynchronous short-range wireless communication between the m-th terminal 200 and the low-power medium from being exposed even when another terminal exists in the asynchronous short-range wireless communication range between the m-th terminal 200 and the low-

The session ID for identifying and managing the asynchronous local area wireless communication session between the m th terminal 200 and the communication chip 105 is determined by the session management unit 138 of the communication chip 105 ). ≪ / RTI > If the asynchronous radio signal for the connection request is repeatedly transmitted a predetermined number of times or more from the m th terminal 200 and the asynchronous radio signal is repeatedly received by the signal receiving unit 134, when the session ID for managing the asynchronous local area wireless communication session between the terminal 200 and the communication chip 105 is generated, the connection admission unit 136 associates with the signal transmitting unit 132, An asynchronous radio signal including the session ID may be transmitted to the terminal 200, and the m th terminal 200 may receive an asynchronous radio signal including the session ID. Upon receiving the asynchronous radio signal including the session ID, the m < th > terminal 200 may recognize that its connection request has been granted based on the session ID. Meanwhile, the m th terminal 200 that transmits the wireless signal for the connection request (or transmits the wireless signal for a predetermined number of times) may transmit an asynchronous wireless signal for requesting the session ID, and the signal receiver 134 May receive an asynchronous radio signal for requesting the session ID. Meanwhile, when an asynchronous radio signal requesting the session ID is received from the m th terminal 200, a session for managing an asynchronous short-range wireless communication session with the m th terminal 200 through the session management unit 138 If the ID is not generated, the connection acknowledgment unit 136 can process the radio signal that is not specific to the receiving side through the signal transmitting unit 132, and if the ID is not generated, When a session ID is generated for managing an asynchronous local area wireless communication session with the m th terminal 200 through the session management unit 138 at the time when an asynchronous radio signal requesting the session ID is received, (136) may process the asynchronous radio signal including the session ID to be transmitted to the m th terminal (200) in cooperation with the signal transmitting unit (132), and the m th terminal The mobile station 200 may receive an asynchronous radio signal including the session ID. Upon receiving the asynchronous radio signal including the session ID, the m < th > terminal 200 may recognize that its connection request has been granted based on the session ID.

The session ID for identifying and managing the asynchronous short-range wireless communication session between the m th terminal 200 and the communication chip 105 is determined by the application 225 of the m th terminal 200, In this case, the session management unit 138 may not generate a separate session ID or perform a procedure for providing the session ID to the m th terminal 200.

1, the communication chip 105 of the low-power medium includes a session ID for interworking with the signal receiving unit 134 to identify asynchronous short-range wireless communication with the access authorized m terminal 200 A generation information receiving unit (140) for receiving and receiving asynchronous signature generation information requesting a signature generation request including a certificate PIN and signature target information, and an asynchronous wireless communication unit for identifying asynchronous short- A session management unit 138 for maintaining a session ID of the signature generation information for a predetermined period of time and a signature processing unit 142 for initiating a procedure for generating an electronic signature value for signature target information while maintaining the session ID .

When the connection of the m th terminal 200 previously designated through the connection acknowledgment unit 136 is approved, the generation information receiving unit 140 interlocks with the signal receiving unit 134, ) And receives the asynchronous signature generation information requesting the signature generation including the certificate PIN and the signature target information.

The terminal 200 that has sent the asynchronous radio signal corresponding to the access request information including the authentication value authenticable through the authentication information (or transmits the asynchronous radio signal for a predetermined number of times or more), or The terminal 200 recognizing the access authorization code or the terminal 200 recognizing the session ID allocated by the session management unit 138 of the communication chip 105 according to the first session management embodiment) Asynchronous signature generation information including a session ID for identifying asynchronous short-range wireless communication with the communication chip 105 and requesting the communication chip 105 to generate a signature including the certificate PIN and signature target information.

If the session management unit 138 of the communication chip 105 allocates a session ID and transmits the session ID through the asynchronous wireless signal according to the first session management embodiment, the m th terminal 200 transmits the asynchronous wireless signal And generate asynchronous signature generation information including the confirmed session ID and requesting the communication chip 105 to generate a signature including the certificate PIN and the signature target information.

Meanwhile, when generating the session ID from the m th terminal 200 according to the second session management embodiment, the m th terminal 200 generates a session ID for identifying the asynchronous local wireless communication with the communication chip 105 And generate asynchronous signature generation information including the generated session ID and requesting the communication chip 105 to generate a signature including the certificate PIN and the signature subject information.

According to an embodiment of the present invention, the m th terminal 200 can generate asynchronous signature generation information including a certificate PIN and signature target information in addition to the session ID generated according to the first or second session management embodiment have.

According to an embodiment of the present invention, asynchronous signature generation information requesting a signature generation through a separate IC chip 150 interfacing with the communication chip 105 in the low-power medium is transmitted to the IC chip 150 A possible APDU command structure, or an information structure that can be processed into the APDU command structure in the communication chip 105. [

According to the first asynchronous signature generation information structure of the present invention, the m th terminal 200 generates asynchronous signature generation information including the session ID and including an APDU command structure injectable into the IC chip 150 And transmits the asynchronous radio signal including the generated asynchronous signature generation information, and the signal receiving unit 134 receives the asynchronous radio signal including the asynchronous signature generation information from the m th terminal 200 , The generation information receiving unit 140 can confirm the asynchronous signature generation information corresponding to the asynchronous radio signal received through the signal receiving unit 134. [

According to the second asynchronous signature generation information structure embodiment of the present invention, the m th terminal 200 generates asynchronous signature generation information that includes the session ID and can be processed into an APDU command structure in the communication chip 105, And transmits the asynchronous radio signal including the generated asynchronous signature generation information, and the signal receiving unit 134 receives the asynchronous radio signal including the asynchronous signature generation information from the m th terminal 200, The generation information receiving unit 140 can confirm the asynchronous signature generation information corresponding to the asynchronous radio signal received through the signal receiving unit 134. [

Meanwhile, according to an embodiment of the present invention, the m th terminal 200 transmits the asynchronous signature generation information (for example, a key for decrypting through a key value stored through the information storage unit 130) The encrypted asynchronous signature generation information may be encrypted (or encrypted through a designated server), and then the asynchronous radio signal including the encrypted asynchronous signature generation information may be transmitted. The generated information reception unit 140 may receive the encrypted asynchronous signature generation information The encrypted asynchronous signature generation information may be decrypted through the key value stored in the information storage unit 130.

According to an embodiment of the present invention, the m th terminal 200 may repeatedly transmit an asynchronous radio signal including the same asynchronous signature generation information a predetermined number of times, It is possible to repeatedly receive the asynchronous radio signal repeatedly transmitted from the mobile station. In this case, the generation information receiver 140 repeatedly receives the asynchronous signature generation information from the m th terminal 200, or normally receives and processes the asynchronous signature generation information that has been received first, Information can be ignored.

Meanwhile, according to the method of the present invention, the data size of information that can be transmitted once from the m th terminal 200 to the communication chip 105 through the asynchronous short-range wireless communication of the present invention can be limited to a specified number of bits. For example, the data size of information that can be transmitted once through the asynchronous short-range wireless communication may be limited to 160 bits (= 20 bytes) or less, and may be limited to a number of bits or more according to an implementation method.

If the asynchronous signature generation information is N (N> n) bits exceeding the designated size n bits (for example, the signature subject information exceeds n bits), the m th terminal 200 transmits the N bits The asynchronous signature generation information is divided into k (k? (Ni)) bit unit data capable of containing the sequence ID of i (i? 1) bits and t (t? And simultaneously transmits t asynchronous radio signals including t bit streams sequentially assigned sequence IDs to each bit stream. The session ID may be included in at least one bitstream among the t bitstreams, and the mth terminal 200 may generate t bitstreams by including a session ID in each of the t bitstreams according to the method. can do.

When the m th terminal 200 transmits t asynchronous radio signals including t bit streams, the signal receiving unit 134 receives u (u t) bit streams from the m th terminal 200 It is able to receive the corresponding u asynchronous radio signals and preferably receive t asynchronous radio signals corresponding to t bit streams.

The generated information receiving unit 140 may hold u bit streams corresponding to u asynchronous radio signals received through the signal receiving unit 134 and may receive t asynchronous radio signals through the signal receiving unit 134 Bit asynchronous signature generation information by combining each k-bit unit data included in the received t bitstreams based on the sequence ID included in t bitstreams corresponding to the t asynchronous wireless signals can do.

Meanwhile, at least one of the bitstreams transmitted through the asynchronous radio signal transmitted from the m th terminal 200 may be lost and not received by the signal receiver 134 or may be received inefficiently. In this case, even if the m th terminal 200 transmits t asynchronous radio signals corresponding to t bitstreams, the generation information receiver 140 may extract at least one bit stream that is not effectively received among the t bitstreams v (v < t) bit streams. The generation information receiving unit 140 reads out the sequence ID included in each bit stream received through the signal receiver 134 to determine whether at least one of the t bit streams is not effectively received (1 &lt; = l &lt; th &gt;) th bit stream that is not effectively received among the t bit streams to be received.

According to the first bitstream re-reception embodiment of the present invention, when the first bit stream that has not been received correctly is identified by reading the sequence ID, the generation information receiver 140 transmits the generated bit stream to the m th terminal 200 (Or the entire bit stream) through the signal transmitting unit 132, and transmits the first bit stream (or the entire bit stream) through the signal transmitting unit 132, Stream from the m-th terminal 200 to transmit the asynchronous radio signal including the stream request information for requesting the first bit stream from the m-th terminal 200.

According to the second bitstream re-reception embodiment of the present invention, the m th terminal 200 performs one cycle of transmitting t asynchronous radio signals corresponding to the t bitstreams, It is possible to repeatedly transmit t asynchronous radio signals corresponding to the predetermined number of times. In this case, the generation information receiving unit 140 can check the first bit stream that has not been received effectively in the previous cycle, and can effectively receive the first stream in the next cycle cycle.

According to the third bitstream re-reception embodiment of the present invention, the generation information receiver 140 receives the first and second bitstreams that have not been received in the form of at least partially combining the first and second bitstream re- It is possible to receive the stream effectively, and thus the present invention is not limited thereto.

When the t bitstreams are validly received from the m th terminal 200 or when the t bitstreams are effectively received through at least one of the first through third bitstream re-reception embodiments, The receiving unit 140 may reconstruct N-bit asynchronous signature generation information by combining k-bit unit data included in the received t bitstreams based on the sequence ID included in the received t bitstreams .

When the asynchronous signature generation information including the session ID and including the certificate PIN and the signature subject information is validly received through the generated information receiving unit 140, the asynchronous signature generation information on the asynchronous local area wireless communication structure according to the present invention The digital signature value is not immediately transmitted to the m th terminal 200 in response to reception (or reception of each bit stream), and the signal transmission unit 132 receives the asynchronous signature generation information (Or an ACK response may be omitted) or a radio signal that does not specify the receiving side may be transmitted, and the wireless communication apparatus may process a wireless signal that does not specify the receiving side The signal including the acknowledgment code recognizable by the m th terminal 200 may be transmitted. Accordingly, even if another terminal exists in the range of asynchronous short-range wireless communication between the mth terminal 200 and the low-power medium, the digital signature value to be generated can be protected from being exposed to other terminals. Preferably, the digital signature value may be transmitted to the mth MS 200 according to separate asynchronous signature request information received from the m th MS 200.

Meanwhile, when the asynchronous signature generation information including the session ID and including the certificate PIN and the signature target information is validly received through the generated information receiving unit 140, the session management unit 138 stores the session ID of the asynchronous signature generation information (For example, stored in the memory unit 125) for a predetermined period of time, thereby managing asynchronous short-range wireless communication with the m th terminal 200.

According to the method of the present invention, the session management unit 138 can initialize the timeout for managing the session ID and start counting each time the information including the session ID is received from the m th terminal 200 And initiates connection approval for the m th terminal 200 when the information including the session ID is not received from the m th terminal 200 for a predetermined period of time or longer (for example, when a timeout elapses) And / or erase the session ID for the m th terminal 200.

Meanwhile, when the asynchronous signature generation information including the session ID and including the certificate PIN and the signature subject information is effectively received through the generated information receiving unit 140, the signature processing unit 142 interlocks with the interface unit 120 And requesting the IC chip 150 for an electronic signature, thereby initiating a procedure for generating an electronic signature value. If the communication chip 105 and the IC chip 150 are implemented in the form of a single chip, the signature processing unit 142 performs a function of the signature generation unit 176 of the IC chip 150, An electronic signature value can be generated.

If the asynchronous signature generation information received through the generated information receiving unit 140 includes the APDU command structure, the signature processing unit 142 may include asynchronous signature generation information including the session ID and include asynchronous short- Signature generation information of the APDU command structure excluding the information and injects an APDU command corresponding to the signature generation information into the IC chip 150 in cooperation with the interface unit 120 to generate the digital signature value Procedures may be initiated.

Meanwhile, when the asynchronous signature generation information received through the generated information receiving unit 140 does not include the APDU command structure, the signature processing unit 142 transmits the asynchronous signature generation information to the IC chip 150 using the received asynchronous signature generation information Generates the signature generation information of a possible APDU command structure and injects the APDU command corresponding to the generated digital signature value generation information into the IC chip 150 in cooperation with the interface unit 120, A procedure for generating the data can be started.

According to an embodiment of the present invention, the signature processing unit 142 injects an APDU command corresponding to the certificate PIN and the signature subject information into the IC chip 150 to generate an electronic signature value through the IC chip 150 Of the procedure.

According to the embodiment of the present invention, the signature processing unit 142 receives the asynchronous signature generation information through the generated information receiving unit 140 and immediately waits for a predetermined time without starting the procedure for generating the digital signature value, (For example, a procedure for injecting an APDU command into the IC chip 150), and even if the signature processing unit 142 immediately starts a procedure for generating an electronic signature value, It is possible to generate an electronic signature value after waiting for a predetermined period of time in the IC chip 150 that generates the value, so that even if another terminal exists in the asynchronous local area wireless communication range between the m th terminal 200 and the low- The digital signature value can be protected from being exposed to other terminals.

The IC chip 150 generates an electronic signature value using a certificate according to a procedure specified in response to the APDU command, and responds (e. G., APDU response) to the electronic signature value as a response to the APDU command.

Referring to FIG. 1, the communication chip 105 of the low-power medium includes the session ID from the m th terminal 200 in cooperation with the signal receiving unit 134, A request information receiving unit 144 for receiving asynchronous signature request information for requesting an electronic signature value, a request information receiving unit 144 for checking whether the digital signature value is generated at the time of receiving the asynchronous signature request information from the m th terminal 200 And a signature verifying unit (146) for verifying whether or not the digital signature value is generated when the digital signature value is not generated at the time of receiving the asynchronous signature request information from the mth MS (200) 200), and when the digital signature value is generated at the time of receiving the asynchronous signature request information from the m th terminal (200), the asynchronous radio signal corresponding to the asynchronous response information is transmitted To 132 for the m-th terminal 200 in association with information and a transmission section 148 for sending the asynchronous wireless signal corresponding to the asynchronous signature information including the session ID and the digital signature value.

The mth terminal 200 transmitting the asynchronous radio signal including the asynchronous signature generation information (or receiving the ACK or the acknowledgment code for the asynchronous signature generation information) includes the session ID and transmits the asynchronous signature generation information And transmits the asynchronous radio signal including the asynchronous signature request information requesting the generated digital signature value to the request information receiver 144. The request information receiver 144 receives the asynchronous signature request information in conjunction with the signal receiver 134. [

Meanwhile, according to an embodiment of the present invention, the m th terminal 200 transmits the asynchronous signature request information (for example, a key for decrypting through a key value stored through the information storage unit 130) (Or may be encrypted through a designated server), and then transmit the asynchronous radio signal including the encrypted asynchronous signature request information, and the request information receiver 144 receives the encrypted asynchronous signature request information The encrypted asynchronous signature request information may be decrypted through the key value stored in the information storage unit 130.

According to an embodiment of the present invention, the m th terminal 200 transmits an asynchronous radio signal including the asynchronous signature generation information (or receives an ACK or an acknowledgment code for the asynchronous signature generation information) An asynchronous radio signal including the asynchronous signature request information may be transmitted after waiting for a predetermined time without transmitting the asynchronous radio signal including the asynchronous signature request information. According to an exemplary embodiment of the present invention, the signature processing unit 142 starts a procedure for generating an electronic signature value after waiting for a predetermined time without starting a procedure for generating an electronic signature value immediately after receiving the asynchronous signature generation information And even if the signature processing unit 142 immediately starts a procedure for generating the digital signature value, it takes a certain time to generate the digital signature value. The m-th terminal 200 transmits the digital signature value The asynchronous radio signal including the asynchronous signature request information may be transmitted after waiting for a predetermined time considering the time required for generating the digital signature value (or the waiting time before starting the procedure for generating the digital signature value). Accordingly, even if another terminal exists in the asynchronous local area wireless communication range between the mth terminal 200 and the low-power medium, the generated digital signature value can be protected from being exposed to other terminals.

When transmitting the asynchronous radio signal including the asynchronous signature request information from the m th terminal 200, the m th terminal 200 repeatedly transmits the asynchronous radio signal including the asynchronous signature request information a predetermined number of times or more In this case, the signal receiver 134 may repeatedly receive the asynchronous radio signal, and the request information receiver 144 may effectively receive at least one asynchronous signature request information.

Meanwhile, when the data size of the asynchronous signature request information transmitted from the mth terminal 200 exceeds the specified n bits, the m th terminal 200 divides the asynchronous signature request information into t bitstreams, In this case, the signal receiver 134 may repeatedly receive t asynchronous radio signals corresponding to t bitstreams, and the request information receiver 144 may receive the t bitstreams And combine them according to the sequence ID to restore the asynchronous signature request information. Meanwhile, the mth MS 200 can transmit the t asynchronous radio signals more than a predetermined number of cycles even when transmitting the t bitstreams, and the request information receiver 144 receives the t asynchronous radio signals from the signal receiver 134 Lt; RTI ID = 0.0 &gt; asynchronous &lt; / RTI &gt;

When the asynchronous signature request information is validly received through the request information receiving unit 144, the signature verifying unit 146 notifies the signature target information included in the asynchronous signature generating information at the time of receiving the asynchronous signature request information (For example, a state in which an electronic signature value generated from the IC chip 150 is received (or acknowledged) via the interface unit 120).

If the digital signature value is not generated at the time of receiving the asynchronous signature request information through the request information receiver 144, the information transmitter 148 may transmit the asynchronous signature request information to the signal transmitter 132, m terminal 200 to transmit the asynchronous response information including the session ID but not including the digital signature value. The asynchronous response information includes an information structure (e.g., an APDU response structure or a predetermined information structure) for responding an electronic signature value to the m th terminal 200, For example, a value that can be recognized as not an electronic signature value). Accordingly, even if another terminal exists in the asynchronous local area wireless communication range between the mth terminal 200 and the low-power medium, the generated digital signature value can be protected from being exposed to other terminals.

According to another embodiment of the present invention, when the digital signature value is not generated at the time of receiving the asynchronous signature request information, the information transmission unit 148 interlocks with the signal transmission unit 132 to specify The present invention is not limited to this. Accordingly, even if another terminal exists in the asynchronous local area wireless communication range between the mth terminal 200 and the low-power medium, the generated digital signature value can be protected from being exposed to other terminals.

Meanwhile, when the digital signature value is generated at the time of receiving the asynchronous signature request information through the request information receiver 144 (for example, when the digital signature value generated from the IC chip 150 through the interface unit 120 (Or responds)), the information transferring unit 148 generates the asynchronous signature information of the specified information structure including the session ID and including the generated digital signature value. For example, the information transmitting unit 148 may generate asynchronous signature information including an APDU response structure.

When the asynchronous signature information of the designated information structure is generated, the information transmitting unit 148 transmits an asynchronous radio signal including the asynchronous signature information to the mth terminal 200 in cooperation with the signal transmitting unit 132 To be sent out.

Meanwhile, according to an embodiment of the present invention, the information transmitter 148 may transmit the asynchronous signature (i. E., The asynchronous signature &lt; RTI ID = 0.0 &gt; And transmits the asynchronous radio signal including the encrypted asynchronous signature information in cooperation with the signal transmitting unit 132. The mth terminal 200 may include the encrypted asynchronous signature information Asynchronous radio signals. According to an embodiment of the present invention, the m th terminal 200 decrypts the encrypted asynchronous signature information through a designated decryption key (e.g., a decryption key corresponding to a key value used to encrypt the asynchronous signature information) . Or the encrypted asynchronous signature information may be transmitted to a designated server having the decryption key and decrypted.

According to an embodiment of the present invention, the information transmitting unit 148 may repeatedly transmit an asynchronous radio signal including the same asynchronous signature information a predetermined number of times, and the short range wireless communication unit 220 of the m- Can repeatedly receive the asynchronous radio signal repeatedly transmitted from the communication chip (105). In this case, the application 225 of the m th terminal 200 repeatedly receives the asynchronous signature information from the communication chip 105, or normally receives and processes the asynchronous signature information that was firstly received correctly, The signature information can be ignored.

Meanwhile, according to the method of the present invention, the data size of information that can be transmitted once from the communication chip 105 to the mth terminal 200 through the asynchronous local area wireless communication of the present invention can be limited to a designated number of bits. For example, the data size of information that can be transmitted once through the asynchronous short-range wireless communication may be limited to 160 bits (= 20 bytes) or less, and may be limited to a number of bits or more according to an implementation method.

If the asynchronous signature information is N (N> n) bits exceeding the designated size n bits (for example, when the digital signature value exceeds the number of n bits), the information transmitting unit 148 transmits the N bits The asynchronous signature information is divided into k (k? (Ni)) bit unit data capable of containing the sequence ID of i (i? 1) bits and t (t? 2) bit streams including k- And simultaneously transmits t asynchronous radio signals including t bit streams sequentially assigned sequence IDs to each bit stream. The session ID may be included in at least one bit stream among the t bit streams, and the information transmitting unit 148 may include a session ID in each t bit streams to generate t bit streams can do.

When transmitting the t asynchronous radio signals including t bitstreams from the communication chip 105, the m th terminal 200 receives u (u) from the communication chip 105 through the short-range wireless communication unit 220, Lt; t) bit streams, and is capable of receiving t asynchronous radio signals, preferably corresponding to t bit streams.

The m th terminal 200 may maintain u bit streams corresponding to u asynchronous radio signals received through the short range wireless communication unit 220 and may transmit t asynchronous radio signals Bit asynchronous signature information included in the received t bitstreams based on the sequence ID included in t bitstreams corresponding to the t asynchronous radio signals, Can be restored.

Meanwhile, at least one of the bitstreams transmitted through the asynchronous radio signal in the communication chip 105 may be lost or not received by the m th terminal 200 or may be received invalid. In this case, even if the communication chip 105 transmits t asynchronous radio signals corresponding to t bitstreams, the m th terminal 200 transmits the asynchronous radio signal of v bits excluding the at least one bit stream that is not effectively received among the t bitstreams (v < t) bit streams can be effectively received. The m th terminal 200 reads the sequence ID included in each bit stream received through the short range wireless communication unit 220 to determine whether at least one of the t bit streams is not effectively received (1 &lt; = l &lt; th &gt;) th bit stream which is not received effectively among the t bit streams to be received.

According to the first bitstream re-reception embodiment of the present invention, when the first bit stream that has not been received correctly is identified by reading the order ID, the m th terminal 200 transmits the bit stream to the communication chip 105 (Or entire bit stream) including the session ID, and transmits the first bit stream (or the entire bit stream) through the short- ) To transmit the asynchronous radio signal including the stream request information requesting the first bit stream from the communication chip 105 to the first chip.

According to the second bitstream re-reception embodiment of the present invention, the information transmission unit 148 performs one cycle of transmitting t asynchronous radio signals corresponding to the t bitstreams, and then transmits the t bitstreams It is possible to repeatedly transmit t asynchronous radio signals corresponding to the predetermined number of times. In this case, the m th MS 200 can check the first bit stream that has not been received effectively in the previous cycle, and can effectively receive the first stream in the next cycle cycle.

According to the third bitstream re-reception embodiment of the present invention, the m th terminal 200 receives at least part of the first through second bit stream re- It is possible to receive the stream effectively, and thus the present invention is not limited thereto.

When the t bit streams are validly received from the communication chip 105 or the t bit streams are effectively received through at least one of the first through third bit stream re-reception embodiments, Bit asynchronous signature information by combining each k-bit unit data included in the received t bitstreams based on the sequence ID included in the received t bitstreams.

The m th terminal 200 may process the digital signature value included in the asynchronous signature information received from the communication chip 105 to be used for the digital signature based authentication procedure.

1, the IC chip 150 of the low-power medium includes a controller 165 for controlling / processing the operation of the IC chip 150, and a controller 165 for storing information necessary for the operation of the IC chip 150 And an interface unit 155 for interfacing communication with the communication chip 105 in the low power medium when the communication chip 105 is provided in the low power medium to interface with the IC chip 150. [ . Meanwhile, when the COB is provided on one surface of the low-power medium, the interface unit 155 can interface with the COB, or the IC chip 150 can interface with the COB through a separate interface.

The control unit 165 is a general term for controlling the operation of the IC chip 150. The control unit 165 includes at least one processor and an execution memory, BUS). According to the present invention, the control unit 165 loads at least one program code provided in the IC chip 150 into the execution memory through the processor, and outputs the result through at least one configuration And controls the operation of the IC chip 150. [0033] FIG. Hereinafter, a functional structure implemented in the form of a program code and / or a control circuit on the IC chip 150 is shown in the control unit 165 for convenience.

The memory unit 160 is a collective term of a nonvolatile memory corresponding to a storage resource of the IC chip 150 and includes at least one program code executed through the control unit 165 and at least one Save and maintain the dataset. The memory unit 160 basically includes a system program code and a system data set corresponding to the operating system of the IC chip 150, a communication program code and a communication data set for processing a communication connection of the IC chip 150, And the program code and data set corresponding to the functional configuration of the present invention are also stored in the memory unit 160. [

The interface unit 155 collectively refers to a configuration for processing low-power medium internal communication between the IC chip 150 and the communication chip 105. The interface unit 155 preferably communicates with the communication chip 105 according to an APDU (Application Protocol Data Unit) ) And half-duplex communication. The interface unit 120 of the communication chip 105 that interfaces with the interface unit 155 within the low power medium at the entrance of the IC chip 150 may be connected to the IC chip 150 It can be recognized as a low power medium reader.

1, the IC chip 150 of the low-power medium includes a certificate storage unit 170 for storing a certificate (for example, a user's authorized certificate, a private certificate, etc.) for digital signatures, An information receiver 172 for receiving signature generation information requesting to generate an electronic signature value from the communication chip 105 through the communication chip 105, a signature generator 176 for performing a procedure for generating an electronic signature value, And a signature providing unit (178) for providing the generated digital signature value to the communication chip (105) through the interface unit (155), the authentication processing unit authenticating the validity of the certificate PIN included in the signature generation information 174).

The certificate storage unit 170 may acquire (e.g., issue, copy, etc.) a certificate for the digital signature and store the certificate in the designated storage area of the memory unit 160. [

According to the first certificate storage embodiment of the present invention, the IC chip 150 may be manufactured / supplied in a state in which the certificate is not stored in a designated storage area (or in a state in which a specified default value is stored) The storage unit 170 confirms whether a valid certificate is stored in the designated storage area of the memory unit 160 (for example, a NULL value or a default value is stored). If a valid certificate is not stored in the designated storage area, the certificate storage unit 170 activates a certificate storage mode for registering a certificate, And transmits the asynchronous radio signal (for example, an asynchronous radio signal or the like whose signal strength has been reduced to be within a range of 1 m to 5 m) specified by the communication chip 105 in cooperation with the chip 105, ) And store the certificate in the designated storage area.

According to the second certificate storage embodiment of the present invention, the IC chip 150 can be manufactured / supplied without storing a certificate in a designated storage area (or storing a specified default value) And a COB for providing a contact interface between the IC chip 150 and the contact IC reader on one side. In this case, the IC chip 150 can receive the certificate from the terminal having the IC reader via the COB and store the certificate in the designated storage area of the memory unit 160. [

According to the third certificate storage embodiment of the present invention, the certificate storage unit 170 acquires a certificate according to a method of at least partially combining at least two of the first to third certificate storage embodiments, And the present invention is not limited thereto.

The IC chip 150 receives information (e.g., authentication information and / or a key value) to be provided to the communication chip 105 through the IC reader, The information storage unit 130 may store the information in the storage area of the communication chip 105 according to a request from the communication chip 105. In this case, ) To the communication chip (105).

When the communication chip 105 receives the asynchronous signature generation information from the m th terminal 200 that is granted access through the asynchronous short distance wireless communication, the communication chip 105 transmits the asynchronous signature generation information corresponding to the asynchronous signature generation information And the information receiving unit 172 receives the APDU command including the signature generation information from the communication chip 105 through the interface unit 155 . Preferably, the signature generation information may include a certificate PIN and signature target information.

The authentication processing unit 174 can authenticate the validity of the certificate PIN included in the signature generation information using the certificate stored in the storage area designated through the certificate storage unit 170. [ The signature providing unit 178 may send a signature to the communication chip 105 when the validity of the certificate PIN is not authenticated, and when the validity of the certificate PIN is not authenticated, And may provide an APDU response that includes a generation error.

The signature generation unit 176 generates an electronic signature value for signature target information included in the signature generation information through a certificate (for example, a private key) stored in a storage area designated through the certificate storage unit 170. [

According to the method of the present invention, the signature generation unit 176 can generate the digital signature value after waiting for a predetermined time, and thus the present invention is not limited thereto.

When the digital signature value is generated through the signature generation unit 176, the signature providing unit 178 transmits an APDU response including the generated digital signature value to the communication chip 105 through the interface unit 155 And the communication chip 105 provides the digital signature value in response to the asynchronous signature request information received from the m th terminal 200 after receiving the digital signature value from the IC chip 150 And transmits the asynchronous signature information of the specified information structure to the m th terminal 200.

2 is a functional block diagram of a terminal 200 according to an embodiment of the present invention.

2 shows a functional configuration of a terminal 200 for generating an electronic signature value by performing asynchronous short-range wireless communication with a low-power medium having an asynchronous local wireless communication function and a certificate-based electronic signature function, Those skilled in the art will be able to refer to and / or modify Figure 2 to illustrate various implementations of the functionality of the terminal 200, but the invention is not limited thereto And the technical features thereof are not limited only by the method shown in FIG. 2 may include at least one of various smart phones capable of wireless communication, various tablet PCs, various PDAs, and various mobile phones, and may include a PC or a notebook computer according to an implementation method .

Referring to FIG. 2, the terminal 200 includes a control unit 202, a memory unit 222, a screen output unit 204, a user input unit 206, a sound processing unit 208, an NFC module 210, A network communication unit 214, a wireless network communication unit 216, a short range wireless communication unit 220, a USIM reader unit 218, and a USIM, and has a battery 212 for power supply.

The control unit 202 is a general term for controlling the operation of the terminal 200. The control unit 202 includes at least one processor and an execution memory. Lt; / RTI &gt; According to the present invention, the control unit 202 loads at least one program code included in the terminal 200 through the processor and performs calculation by loading the program code into the execution memory, and outputs the result to at least one constituent unit And controls the operation of the terminal 200. Hereinafter, the configuration of the program 225 of the present invention, which is implemented in the form of program code for convenience, will be described in the control unit 202.

The memory unit 222 is a generic term of a nonvolatile memory corresponding to a storage resource of the terminal 200 and includes at least one program code executed through the control unit 202 and at least one data used by the program code Save and keep the set. The memory unit 222 basically comprises a system program code and a system data set corresponding to the operating system of the terminal 200, a communication program code and a communication data set for processing a wireless communication connection of the terminal 200, The program code and the data set corresponding to the program 225 of the present invention are also stored in the memory unit 222. In addition,

The screen output unit 204 includes a screen output unit (e.g., an LCD (Liquid Crystal Display) and the like) and a driving module for driving the screen output unit 204. The screen output unit 204 is interlocked with the control unit 202, And outputs an operation result corresponding to the output to the screen output device.

The user input unit 206 includes at least one user input device such as a button, a keypad, a touch pad, a touch screen interlocked with the screen output unit 204, and a drive module for driving the touch screen. And inputs a command for instructing various operations of the control unit 202 or data necessary for the operation of the control unit 202. [

The sound processing unit 208 includes a speaker, a microphone, and a drive module for driving the sound processing unit 208. The sound processing unit 208 decodes sound data corresponding to a sound output from various calculation results of the control unit 202 and outputs the sound data through the speaker , Or a sound signal input through the microphone, and transmits the encoded sound signal to the controller 202.

The NFC module 210 may be a communication resource for processing one or more proximity wireless communications between a bi-directional proximity wireless communication, a full-duplex proximity wireless communication, and a half-duplex proximity wireless communication using a radio frequency signal as a communication medium at a close distance (e.g., , And is capable of processing proximity wireless communication according to the NFC (Near Field Communication) standard of the 13.56-MHz frequency band.

The wireless network communication unit 216 and the local area network communication unit 214 are collectively referred to as communication resources for connecting the terminal 200 to a designated communication network. Preferably, the terminal 200 may include a wireless network communication unit 216 as a basic communication resource, and may include one or more short-range network communication units 214.

The wireless network communication unit 216 is a collective term for a communication resource that connects the terminal 200 to a wireless communication network via a base station and includes an antenna for transmitting and receiving a radio frequency signal of a specific frequency band, And transmits the calculation result corresponding to the wireless communication among the various calculation results of the controller 202 through the wireless communication network or receives the data through the wireless communication network To the control unit 202, and performs the connection, registration, communication, and handoff procedures of the wireless communication. According to the present invention, the wireless network communication unit 216 can connect the terminal 200 to a call network including a call channel and a data channel via the exchange, and in some cases, To a data network that provides wireless network data communication (e.g., the Internet).

According to an embodiment of the present invention, the wireless network communication unit 216 may be a mobile communication unit that performs at least one connection, a location registration, a call processing, a call connection, a data communication, and a handoff to a mobile communication network according to the CDMA / WCDMA / &Lt; / RTI &gt; Meanwhile, according to the intention of a person skilled in the art, the wireless network communication unit 216 may further include a portable Internet communication configuration for performing at least one of connection to the portable Internet, location registration, data communication, and handoff according to the IEEE 802.16 standard, It is evident that the present invention is not limited by the wireless communication configuration provided by the wireless network communication unit 216. [ That is, the wireless network communication unit 216 is a general term for a configuration unit that connects to a wireless communication network through a cell-based base station irrespective of a frequency band of a wireless zone, a type of a communication network, or a protocol.

The short-range network communication unit 214 is a collective term for a communication resource that connects a communication session using a radio frequency signal as a communication medium within a predetermined distance and connects the terminal 200 to the communication network based on the communication session, , The public wireless communication, and the UWB, the terminal 200 can be connected to the communication network. According to an embodiment of the present invention, the short-range network communication unit 214 may be integrated with or separated from the wireless network communication unit 216. According to the present invention, the short-range network communication unit 214 connects the terminal 200 to a data network providing packet-based short-range wireless data communication through a wireless AP.

The USIM reader unit 218 is a collective term for a configuration in which at least one data set is exchanged with a universal subscriber identity module that is mounted or detached from the terminal 200 based on the ISO / IEC 7816 standard , The data set is exchanged in a half-duplex communication manner through an APDU (Application Protocol Data Unit).

The USIM is an SIM type card according to the ISO / IEC 7816 standard, and includes an input / output interface including at least one contact connected to the USIM reader unit 218, a memory for storing at least one program code and a data set, And a processor connected to the input / output interface and calculating the program code according to at least one command transmitted from the terminal 200, or extracting (or processing) the data set and transmitting the data to the input / output interface.

The short-range wireless communication unit 220 is a collective term for short-range wireless communication with a short-range communication medium (for example, the low-power medium in FIG. 1) located in a short distance within a designated communication range (for example, within a maximum of 100 m) And a function of receiving or transmitting an asynchronous radio signal for asynchronous short-range wireless communication according to the present invention. For example, the short-range wireless communication unit 220 may include a Bluetooth module of Bluetooth standard 4.0 or later. However, the short-range wireless communication unit 220 is not limited to the Bluetooth module, and the short-range wireless communication unit 220 may be configured to receive or transmit the asynchronous wireless signal for asynchronous short- 220). Meanwhile, the near-field communication unit 214 and the short-range wireless communication unit 220 may be integrated into one component according to an embodiment of the present invention, and thus the present invention is not limited thereto.

The program 225 of the present invention is downloaded from a designated program providing server (for example, an Apple App Store or the like) through a data network connectable via the communication resource and is recorded in the memory unit 222, do.

Referring to FIG. 2, the program 225 of the terminal 200 includes an authentication value storage unit 230 for storing an authentication value for requesting a connection to the communication chip 105 of the low-power medium shown in FIG. 1 And an encryption / decryption key storage unit 235 for storing an encryption key and / or a decryption key for secure communication with the communication chip 105 of the low-power medium.

The authentication value storage unit 230 identifies an authentication value for receiving a connection request of the terminal 200 through the authentication information stored in the communication chip 105 of the low power medium, Area. For example, the authentication value may include a telephone number, a device ID, and the like assigned to the terminal 200, and / or may include an initial activation (or authentication) after the program 225 is installed in the terminal 200 The communication chip 105 of the low power medium may include at least one of eigenvalues uniquely assigned to the terminal 200 that has executed the program 225 according to a designated procedure at the time of setting Storing the authentication information for authenticating the authentication value according to at least one of the first to fifth communication information storing embodiments. Alternatively, after the authentication information is stored in the communication chip 105 of the low-power medium according to at least one of the first to fifth information storage embodiments, the authentication value storage unit 230 may store the authentication information (For example, receiving from the server managing the low-power medium) an authentication value that can be authenticated and storing the authentication value in a designated storage area of the memory unit 222. [ Preferably, the authentication value storage unit 230 stores the authentication information in association with the ID information included in the wireless signal transmitted from the communication chip 105 of the low-power medium without characterizing the receiving side.

The encryption / decryption key storage unit 235 stores a decryption key for decrypting the encrypted information through the key value stored in the communication chip 105 of the low-power medium and / or a key value stored in the communication chip 105 of the low- And stores the encrypted key in the designated storage area of the memory unit 222. Preferably, the encryption / decryption key storage unit 235 communicates with the server managing the low-power medium to store the encryption key and / or the decryption key in a designated storage area.

Referring to FIG. 2, the program 225 of the terminal 200 receives an asynchronous radio signal transmitted from the communication chip 105 of the low-power medium through the short- A low power medium identification unit 240 for identifying the low power medium from which the asynchronous radio signal is transmitted, and an asynchronous wireless communication unit 240 for requesting connection to the communication chip 105 of the low power medium through the short range wireless communication unit 220. [ And a session processor (not shown) for establishing or managing a session for performing asynchronous short-range wireless communication with the communication chip 105 of the low-power medium through the short-range wireless communication unit 220 through a connection request unit 245, (250).

When an asynchronous radio signal that does not specify a receiving side is transmitted from the communication chip 105 of the low-power medium, the communication chip 105 of the low-power medium and the local wireless communication section of the terminal 200 located in the designated local communication range The asynchronous radio signal receiving unit 220 receives the asynchronous radio signal transmitted from the communication chip 105 of the low power medium and the low power medium check unit 240 reads the unique ID information included in the asynchronous radio signal, (E.g., communication chip 105 of low-power medium). Preferably, the communication chip 105 of the low-power medium transmitting the asynchronous radio signal operates in a server mode (or a master mode).

When the low power medium having transmitted the asynchronous radio signal is identified, the connection request unit 245 transmits the asynchronous radio signal to the asynchronous wireless communication unit 220 through the short- And sends a wireless signal to the communication chip 105 of the low-power medium. Preferably, the access request information may include an authentication value for access authorization of the terminal 200.

According to an embodiment of the present invention, an asynchronous radio signal including the connection request information may be transmitted over a specified number of times of requesting the connection, and an asynchronous radio signal may be transmitted from the communication chip 105 of a low- And decrypts the connection request information through a decryptable encryption key), and then transmits the asynchronous radio signal including the encrypted connection request information. On the other hand, when the connection request information is contained in one asynchronous radio signal and exceeds the designated n bits (for example, exceeding n bits by encryption) according to the method of operation, the connection request unit 245 requests the connection In this case, the communication chip 105 of the low-power medium can recover the connection request information by combining the divided bitstreams.

The communication chip 105 of the low-power medium receives an asynchronous radio signal for requesting connection of the terminal 200, and transmits access request information (e.g., authentication value) included in the asynchronous radio signal through the previously registered authentication information, And confirms the connection request of the terminal 200. On the other hand, even if the communication chip 105 of the low-power medium transmits the asynchronous radio signal corresponding to the ACK of the asynchronous radio signal for the connection request of the terminal 200, the asynchronous radio signal corresponding to the ACK is not acknowledged And transmits the asynchronous radio signal including the acknowledgment result of the terminal 200 or the acknowledgment result (or the access acknowledgment code) to a separate asynchronous radio signal even if the asynchronous radio signal is not transmitted. It can send out.

The session processing unit 250 generates a session ID for identifying the asynchronous local area wireless communication with the communication chip 105 of the low-power medium through the local area wireless communication unit 220 and maintains the session ID for a predetermined period of time, Receiving the asynchronous radio signal including the session ID for identifying the asynchronous short-range wireless communication between the terminal 200 and the communication chip 105 of the low-power medium from the communication chip 105 of the low-power medium, .

Referring to FIG. 2, the program 225 of the terminal 200 transmits an asynchronous radio signal including asynchronous signature generation information to the communication chip 105 of the low-power medium through the short-range wireless communication unit 220 And a generation request unit 255 for requesting generation of a signature.

(Or sending) the asynchronous radio signal for the connection request from the program 225 of the terminal 200 to the communication chip 105 of the low-power medium, and / or transmitting the asynchronous radio signal to the communication chip 105) receives an asynchronous radio signal including an approval result (or a connection approval code) for the connection request, the generation request unit 255 requests the communication chip 105 of the low-power medium to generate a signature And generates an asynchronous signature including the asynchronous signature generation information to the communication chip 105 of the low-power medium through the short-range wireless communication unit 220, And requests the medium to generate an electronic signature value.

According to an embodiment of the present invention, the generation request unit 255 includes a session ID for identifying asynchronous short-range wireless communication with the communication chip 105 of the low-power medium, and includes a certificate PIN and signature subject information, Generates asynchronous signature generation information for requesting signature generation by the communication chip 105 and transmits an asynchronous radio signal including asynchronous signature generation information to the communication chip 105 of the low-power medium through the short-range wireless communication unit 220 . Preferably, the asynchronous signature generation information may include an information structure corresponding to the first or second asynchronous signature generation information structure embodiment.

According to an embodiment of the present invention, the generation request unit 255 transmits the asynchronous signature generation information through a designated encryption key (for example, a key that is decryptable through a key value stored through the information storage unit 130) After encrypting (or encrypting via a designated server), the asynchronous wireless signal including the encrypted asynchronous signature generation information may be processed to be transmitted.

According to the embodiment of the present invention, the generation request unit 255 can repeatedly transmit the asynchronous radio signal including the same asynchronous signature generation information over a specified number of times.

If the asynchronous signature generation information is N (N> n) bits exceeding the designated size n bits (for example, when the signature target information exceeds n bits), the generation request unit 255 generates N bits The asynchronous signature generation information is divided into k (k? (Ni)) bit unit data capable of containing the sequence ID of i (i? 1) bits and t (t? And simultaneously transmits t asynchronous radio signals including t bit streams sequentially assigned sequence IDs to each bit stream. The session ID may be included in at least one bitstream among the t bitstreams, and the generation request unit 255 generates t bitstreams by including a session ID in each of the t bitstreams according to an implementation method. can do.

When the generation request unit 255 transmits t asynchronous radio signals including t bitstreams, the communication chip 105 of the low-power medium transmits u bits corresponding to the u (u t) It may receive asynchronous radio signals and preferably receive t asynchronous radio signals corresponding to t bit streams.

The communication chip 105 of the low power medium may maintain u bitstreams corresponding to the received u asynchronous radio signals and may transmit t tones corresponding to the t asynchronous radio signals when t asynchronous radio signals are received It is possible to reconstruct N-bit asynchronous signature generation information by combining each k-bit unit data included in the received t bitstreams based on the sequence ID included in the bitstream.

When the t bitstreams are validly received or the t bitstreams are effectively received through at least one of the first through third bitstream redistribution embodiments, the communication chip (105) of the low- It is possible to reconstruct N-bit asynchronous signature generation information by combining k-bit unit data included in the received t bitstreams based on the sequence ID included in the received t bitstreams.

The communication chip 105 of the low-power medium may initiate a procedure for generating an electronic signature value based on the asynchronous signature generation information. Preferably, the electronic signature value may include an IC chip 150 provided in the low- Lt; / RTI &gt;

According to an embodiment of the present invention, it is preferable that the communication chip 105 of the low-power medium does not transmit asynchronous signature information including an electronic signature value as a response to receive the asynchronous signature generation information, It is preferably transmitted through separate asynchronous signature request information.

Referring to FIG. 2, a program 225 of the terminal 200 transmits an asynchronous radio signal including asynchronous signature request information to the communication chip 105 of the low-power medium through the short-range wireless communication unit 220 A signature requesting unit 260 for requesting an electronic signature value generated in the low power medium by processing the low power medium, and a signature requesting unit 260 for requesting an electronic signature value generated in the asynchronous radio signal transmitted from the communication chip 105 of the low power medium, A signature receiving unit 265 for confirming asynchronous signature information and a signature value verifying unit 270 for verifying an electronic signature value included in the asynchronous signature information, And an authentication procedure unit 275 for performing an electronic signature-based authentication procedure using the digital signature value.

(Or more than a specified number of times) the asynchronous radio signal including the asynchronous signature generation information to the communication chip 105 of the low-power medium, and / or transmits the asynchronous signature generation information from the communication chip 105 of the low- The signature request unit 260 generates the asynchronous signature request information including the session ID and requests the generated digital signature value based on the asynchronous signature generation information, Requesting the communication chip 105 of the low-power medium to transmit the asynchronous radio signal including the asynchronous signature request information through the short-range wireless communication unit 220 to provide the digital signature value generated in the low-power medium.

Meanwhile, the signature requesting unit 260 transmits (or transmits) the asynchronous radio signal including the asynchronous signature generation information more than a predetermined number of times, and / or transmits the asynchronous signature generating information from the communication chip 105 of the low- The asynchronous mobile station may process the asynchronous radio signal including the asynchronous signature request information after waiting for a certain period of time after the ACK or the acknowledgment code is received, so that the present invention is not limited thereto.

According to an embodiment of the present invention, the signature request unit 260 transmits the asynchronous signature request information through a designated encryption key (for example, a key that is decryptable through a key value stored in the information storage unit 130) After encrypting (or encrypting via a designated server), the asynchronous radio signal including the encrypted asynchronous signature request information may be transmitted.

According to an embodiment of the present invention, the signature requesting unit 260 may repeatedly transmit an asynchronous radio signal including the same asynchronous signature request information for a predetermined number of times or more.

According to the embodiment of the present invention, when the asynchronous signature request information is contained in one asynchronous radio signal and exceeds the specified n bits which can be transmitted (for example, In this case, the communication chip 105 of the low-power medium combines the divided bitstreams to recover the asynchronous signature request information. .

Upon receiving the asynchronous signature request information, the communication chip 105 of the low-power medium, which has received the asynchronous signature request information, determines whether the digital signature value of the signature target information included in the asynchronous signature generation information has been generated Check.

If the digital signature value is not generated at the time of receiving the asynchronous signature request information, the communication chip 105 of the low-power medium transmits the session ID to the terminal 200 but does not include the digital signature value And processes to transmit the asynchronous response information. The asynchronous response information includes an information structure (e.g., an APDU response structure or a predetermined information structure) for responding to an electronic signature value to the terminal 200. The asynchronous response information includes a NULL value or a specified default value (e.g., A value that can recognize that the digital signature is not a digital signature value). In this case, the signature receiving unit 265 can confirm the asynchronous response information corresponding to the asynchronous radio signal received through the short-range wireless communication unit 220. [ However, since the asynchronous response information does not include a valid digital signature value, it is preferable to ignore it.

According to another embodiment of the present invention, when the digital signature value is not generated at the time of receiving the asynchronous signature request information, the communication chip 105 of the low-power medium transmits an asynchronous radio signal that does not specify the receiving side The present invention is not limited thereto.

Meanwhile, when the digital signature value is generated at the time of receiving the asynchronous signature request information, the communication chip 105 of the low-power medium includes the session ID, and the asynchronous signature information of the specified information structure including the generated digital signature value And generates signature information. For example, the communication chip 105 of the low power medium may generate asynchronous signature information including an APDU response structure.

When the asynchronous signature information of the specified information structure is generated, the communication chip 105 of the low-power medium processes the asynchronous radio signal including the asynchronous signature information to be sent to the terminal 200, and the signature receiver 265 Confirms the asynchronous signature information corresponding to the asynchronous radio signal received through the short-range wireless communication unit 220. [

Meanwhile, according to an embodiment of the present invention, the communication chip 105 of the low-power medium encrypts the asynchronous signature information so as to be decryptable through the terminal 200 (or a designated server) through the registered key value, And transmits the asynchronous radio signal including the asynchronous signature information to the signature receiving unit 265. The signature receiving unit 265 confirms the encrypted asynchronous signature information corresponding to the asynchronous radio signal received through the short range wireless communication unit 220, And can decrypt the encrypted asynchronous signature information through a designated decryption key.

According to the embodiment of the present invention, the communication chip 105 of the low-power medium can repeatedly transmit an asynchronous radio signal including the same asynchronous signature information a predetermined number of times, and the signature receiving unit 265 transmits the asynchronous radio signal And valid asynchronous signature information based on the wireless signal.

If the asynchronous signature information is N (N> n) bits exceeding the designated size n bits (for example, when the digital signature value exceeds n-bit number), the communication chip 105 of the low- Bit asynchronous signature information into k (k &lt; = (ni)) bit unit data capable of containing the sequence ID of i (i? 1) And simultaneously transmits t asynchronous radio signals including t bit streams obtained by sequentially assigning sequence IDs to each bit stream. And the session ID may be included in at least one of the t bit streams. According to an embodiment of the present invention, the communication chip 105 of the low-power medium may include a session ID in each of t t bit streams, Can be generated.

When transmitting the t asynchronous radio signals including t bitstreams from the communication chip 105 of the low-power medium, the signature receiver 265 transmits the asynchronous radio signal to the communication chip 105 of the low-power medium through the short- ) U u (u? T) bit streams, and may preferably receive t asynchronous radio signals corresponding to t bit streams.

The signature receiving unit 265 may maintain u bit streams corresponding to u asynchronous radio signals received through the short-range wireless communication unit 220 and may transmit t asynchronous radio signals through the short- If the asynchronous radio signal is received, combines each k-bit unit data included in the received t bit streams based on the sequence ID included in t bit streams corresponding to the t asynchronous radio signals to restore N-bit asynchronous signature information can do.

The signature value checking unit 270 reads an information structure corresponding to the asynchronous signature information received from the low power medium communication chip 105 and confirms (or extracts) the electronic signature value included in the asynchronous signature information.

The authentication procedure unit 275 performs an electronic signature based authentication using an electronic signature value confirmed (or extracted) by the signature value verification unit 270 in cooperation with the wireless network communication unit 216 or the short- Perform the procedure.

FIG. 3 is a diagram illustrating a process of connecting to a communication chip 105 of a low-power medium through asynchronous short-range wireless communication in a terminal 200 according to an embodiment of the present invention.

3 illustrates a program 225 of the terminal 200 shown in FIG. 2, which is operated in a server mode (or master mode) using asynchronous short-range wireless communication, 105 of the terminal 200, the terminal 200 receives and approves access to the terminal 200. As a person skilled in the art, referring to FIG. 3 and / It is to be understood that the invention may be practiced otherwise than as specifically described herein, but it is to be understood that the invention may be practiced otherwise than as specifically described herein, The technical features are not limited by the method alone. Hereinafter, for the sake of convenience, FIG. 3 is a block diagram illustrating an exemplary embodiment of the present invention. Referring to FIG. 3, when the n bits of information transmitted / received through the asynchronous short- And the process of restoring it will be omitted for the sake of convenience, but it will be evident that the processes omitted in FIG. 3 can be included as needed.

Referring to FIG. 3, the communication chip 105 of the low power medium of FIG. 1 includes authentication information for accepting an asynchronous connection request of the specific terminal 200 when a specific terminal 200 requests connection through asynchronous short- And stores it in a designated storage area in the communication chip 105 (300). The communication chip 105 of the low-power medium confirms a key value for encryption / decryption between the specific terminal 200 and the communication chip 105 of the low-power medium during the asynchronous short-range wireless communication process with the specific terminal 200 And store it in a designated storage area in the communication chip 105 (300). Preferably, the communication chip 105 of the low-power medium communicates the authentication information and / or the key value to the communication chip of the low-power medium based on at least one embodiment of the information storage embodiments for the first through fifth aspects of the present invention 105).

Meanwhile, the terminal 200 of FIG. 2 designated to perform asynchronous short-range wireless communication with the communication chip 105 of the low-power medium receives the asynchronous access request to the communication chip 105 of the low-power medium through asynchronous short- And confirms the authentication value and stores it in the designated storage area of the terminal 200 (305). According to an embodiment of the present invention, the terminal 200 identifies an encryption / decryption key for encryption / decryption with the communication chip 105 of the low-power medium during asynchronous short-range wireless communication with the communication chip 105 of the low- (305). &Lt; / RTI &gt;

Thereafter, when a button operation on one side of the low-power medium occurs (310), the communication chip 105 of the low-power medium transmits (315) an asynchronous radio signal that does not specify the receiving side, The communication chip 105 of the low power medium and the M terminals 200 in the designated short range wireless communication range receive the asynchronous radio signal transmitted from the communication chip 105 of the low power medium without specifying the receiving side, 2 of the M terminals 200 reads the asynchronous radio signal and checks (330) a low-power medium from which the asynchronous radio signal is transmitted (330). The terminal 200 shown in FIG. And transmits the asynchronous radio signal to the communication chip 105 of the low-power medium (335). According to an embodiment of the present invention, the m th terminal 200 designated to perform asynchronous short distance wireless communication with the communication chip 105 of the low power medium among the M terminals 200 encrypts the connection request information, Alternatively, if the connection request information exceeds the designated n bits according to the method of operation, it may be divided into t bit streams and transmitted.

The communication chip 105 of the low-power medium can receive an asynchronous radio signal for M connection requests from M terminals 200 existing in the short-range wireless communication range and confirms a connection request from the M terminals 200 (340). On the other hand, the communication chip 105 of the low-power medium does not immediately respond to a response including information related to connection approval or rejection for the M connection requests. However, the communication chip 105 does not respond asynchronously (345) a wireless signal (345) or transmit a wireless signal that does not specify a receiving side (345), and M terminals (200) in a short range wireless communication range with the chip of the low- (350). That is, since the communication chip 105 of the low-power medium does not immediately respond to the connection request of the M terminals 200 to approve the connection or refuse the connection, it attempts to perform a hacking attack such as an assignment attack among the M terminals 200 Even if the terminal to be used exists, such an attempt can not be made.

The communication chip 105 of the low-power medium performs a connection approval procedure to approve a connection request of a predetermined m th terminal 200 among the M terminals 200 using the registered authentication information (355). If the connection request information included in the asynchronous radio signal for the connection request is encrypted, the communication chip 105 of the low-power medium can perform the connection procedure after decoding the encrypted connection request information, Is divided and received by t bit streams, the connection procedure can be performed after restoring it. If the connection request of the m th terminal 200 is approved, the communication chip 105 of the low power medium transmits an asynchronous signal including an approval result (or a connection approval code) The wireless signal can be transmitted (365). According to an embodiment of the present invention, the m th terminal 200 transmits (360) an asynchronous radio signal for the connection request more than a specified number of times, or transmits an asynchronous radio signal (360), the communication chip 105 of the low-power medium may transmit the asynchronous radio signal received from the m th terminal 200 after the connection approval of the m th terminal 200 is confirmed An asynchronous radio signal including an approval result of the m th terminal 200 may be transmitted (365). Alternatively, the communication chip 105 of the low-power medium may transmit an asynchronous radio signal including the access authorization code of the m th terminal 200 using an asynchronous radio signal that does not specify the receiving side (365). Or may not transmit an asynchronous radio signal that can confirm the connection approval of the m th terminal 200 according to the method.

When the asynchronous radio signal including the approval result (or the access authorization code) approved by the communication chip 105 of the low-power medium is transmitted (365), the m-th terminal 200 receives an asynchronous radio signal including an approval result (or access authorization code) for approving the connection of the m th terminal 200 (370) (375).

4 is a diagram illustrating a process of requesting a terminal 200 to generate a signature from a low-power medium through asynchronous short-range wireless communication according to an embodiment of the present invention.

4 shows a process in which the program 225 of the terminal 200 shown in FIG. 2 requests signature generation to the communication chip 105 of the low-power medium of FIG. 1 through asynchronous short-range wireless communication Those skilled in the art will appreciate that various modifications and variations of the method for requesting signature generation (e.g., some steps may be omitted, or steps may be omitted) However, the present invention includes all of the above-described embodiments, and the technical features of the present invention are not limited only by the method shown in FIG. Hereinafter, for the sake of convenience, FIG. 4 is a block diagram illustrating an example in which, when n bits of information transmitted / received through the asynchronous short-range wireless communication between the terminal 200 and the communication chip 105 of the low- And the process of restoring it will be omitted for the sake of simplicity, but it is evident that the processes omitted in FIG. 4 can be included as needed.

Referring to FIG. 4, the m-th terminal 200 requesting connection to the communication chip 105 of the low-power medium through the process of FIG. 3 or confirming the connection approval for the connection request is connected to the communication chip 105 of the low- (400) to include asynchronous signature generation information including a session ID and a certificate PIN and signature target information to request a signature generation. The session ID is allocated in the communication chip 105 of the low-power medium according to the first session management embodiment of the present invention and transmitted to the mth terminal 200 through the asynchronous radio signal, And may be determined in the mth terminal 200 according to an example.

The m-th terminal 200 transmits an asynchronous radio signal including the generated asynchronous signature generation information to the communication chip 105 of the fraudulent low-power medium to request signature generation (405). According to an embodiment of the present invention, the m th terminal 200 may encrypt the asynchronous signature generation information and transmit it through an asynchronous radio signal, or the asynchronous signature generation information may be transmitted in excess of the specified n bits It can be divided into t bit streams and transmitted.

Meanwhile, the communication chip 105 of the low-power medium which has approved the connection of the m th terminal 200 through the process of Fig. 3 includes the session ID from the m th authorized terminal 200, (410) for receiving asynchronous signature generation information including information, and includes a session ID for identifying and managing asynchronous short-range wireless communication with the m th terminal (200) during the reception, And receives an asynchronous radio signal corresponding to the asynchronous signature generation information (415). On the other hand, the communication chip 105 of the low-power medium does not immediately respond to the response of the digital signature value to the receipt of the asynchronous signature generation information, but transmits an asynchronous radio signal including an ACK for the signature generation request (420) or transmit a radio signal that does not specify a receiver (420), and the m th terminal (200) may receive the asynchronous radio signal (425). If there is another terminal capable of transmitting and receiving the asynchronous radio signal in addition to the m th terminal 200 in the short range communication range of the low power medium with the communication chip 105, Since the digital signature value is not responded to the signature generation request of the terminal 200 immediately, the digital signature value is blocked as well as the hacking attempt of the other terminal is blocked.

The communication chip 105 of the low-power medium confirms the asynchronous signature generation information included in the asynchronous radio signal received from the m th terminal 200 (430). If the asynchronous signature generation information included in the asynchronous radio signal for the connection request is encrypted, the communication chip 105 of the low power medium can decrypt the encrypted asynchronous signature generation information, If the bitstream is divided and received, it can be restored.

The communication chip (105) of the low-power medium which has confirmed the asynchronous signature generation information received from the m th terminal (200) is used for identifying asynchronous short-range wireless communication with the m th terminal (200) (440) a session ID for identifying the asynchronous local area wireless communication with the m th terminal 200 for a predetermined period of time (440) The mobile terminal 200 checks whether an asynchronous radio signal is additionally received from the terminal 200. If the asynchronous radio signal is additionally received from the m th terminal 200 within a predetermined period of time, (440) repeating the process of maintaining the session ID for managing the communication for a specified period of time (or restarting the time after initializing the time) (450a) and / or initializes (450a) the connection approval for the m th terminal (200) when the asynchronous radio signal is not additionally received from the m th terminal (200) The ID can be erased (450b).

On the other hand, the communication chip 105 of the low-power medium which has confirmed the asynchronous signature generation information received from the m th terminal 200 receives the asynchronous signature generation information from the IC chip 150 having the certificate-based digital signature function of the low- The signature generation information of the APDU command structure to be injected is confirmed (455). The signature generation information may be included in the asynchronous signature generation information and may be received from the m th terminal 200 or may be generated based on the asynchronous signature generation information in the communication chip 105 of the low power medium.

The communication chip 105 of the low-power medium includes the signature generation information to the IC chip 150 having the certificate-based electronic signature function through the interface in the low-power medium between the communication chip 105 and the IC chip 150 (460), it is confirmed whether an APDU response including an electronic signature value is received from the IC chip 150 via the interface in the low-power medium between the communication chip 105 and the IC chip 150 (465).

According to the embodiment of the present invention, the IC chip 150 can generate an electronic signature value through the process of FIG. 5 and respond to the communication chip 105. The communication chip 105 of the low-power medium receives the asynchronous signature request information from the m th terminal 200 through the process of FIG. 6 and the digital signature value generated from the IC chip 150 through the process of FIG. The mobile terminal 200 may transmit the asynchronous radio signal including the other information to the m th terminal 200.

FIG. 5 illustrates a process of generating an electronic signature value based on asynchronous short-range wireless communication in a low-power medium according to an embodiment of the present invention.

5 illustrates signature generation information provided by the IC chip 150 of the low-power medium in the communication chip 105 of the low-power medium shown in FIG. 1, the digital signature value of the IC chip 150 of the low- Those skilled in the art will appreciate that various modifications and variations of the method of generating the signature (e.g., some steps may be omitted or omitted) , Or an embodiment in which the order is changed). However, the present invention includes all of the above-described embodiments, and the technical features of the present invention are not limited only by the method shown in FIG.

Referring to FIG. 5, the IC chip 150 of the low power medium of FIG. 1 confirms the certificate and stores it in a designated storage area (500). Preferably, the IC chip 150 of the low-power medium may store the certificate in the IC chip 150 of the low-power medium based on at least one embodiment of the first through third certificate storage embodiments of the present invention .

4, the communication chip 105 of the low-power medium communicates with the IC chip 150 via the interface in the low-power medium between the communication chip 105 and the IC chip 150, The IC chip 150 receives the signature generation information from the communication chip 105 through the interface in the low-power medium between the communication chip 105 and the IC chip 150 (505) .

The IC chip 150 of the low-power medium may perform a procedure for authenticating the validity of the certificate PIN 510. If the validity of the certificate PIN is not authenticated, the IC chip 150 of the low- (515) an APDU response including a signature generation error to the communication chip (105) through an interface in the low power medium between the communication chip (105) and the IC chip (150).

Meanwhile, when the validity of the certificate PIN included in the signature generation information is authenticated, the IC chip 150 of the low-power medium uses the certificate (for example, a private key) stored in the IC chip 150, And generates a digital signature value for the included signature target information (520).

If an electronic signature value for the signing object information is generated, the IC chip 150 of the low-power medium communicates with the communication chip 105 via the interface in the low-power medium between the communication chip 105 and the IC chip 150 And provides an APDU response including the generated digital signature value (525).

According to the method of the present invention, the time when the digital signature value is provided from the IC chip 150 to the communication chip 105 through the process of FIG. 5 and the communication chip 105 of the low- The communication chip 105 of the low power medium may transmit the asynchronous radio signal including the other information to the m th terminal 200 according to the time when the asynchronous signature request information is received from the m th terminal 200 through the m th terminal 200.

FIG. 6 is a diagram illustrating a process of requesting an electronic signature value from a low-power medium through asynchronous short-range wireless communication in a terminal 200 according to an embodiment of the present invention.

In more detail, FIG. 6 illustrates a program 225 of the terminal 200 shown in FIG. 2 requesting and providing an electronic signature value to the communication chip 105 of the low power medium of FIG. 1 via asynchronous local area wireless communication 6 is a flowchart illustrating a method of providing digital signatures according to an exemplary embodiment of the present invention. Referring to FIG. 6, However, it should be understood that the present invention is not limited to the above-described embodiments, and may be modified in various ways. Hereinafter, for the sake of convenience, FIG. 6 is a block diagram illustrating an example of a method for transmitting / receiving data by dividing a bit stream into t bitstreams when n bits of information transmitted / received through the asynchronous short- And the process of restoring it will be omitted for the sake of simplicity, but it is clear that the processes omitted in FIG. 6 can be included as needed.

Referring to FIG. 6, the m th terminal 200 transmits (or transmits) an asynchronous radio signal including asynchronous signature generation information to the communication chip 105 of a low-power medium through the process of FIG. 4, Generates asynchronous signature request information including a session ID (600) to request the electronic signature value generated based on the asynchronous signature generation information to the communication chip (105) of the low power medium, and transmits the generated asynchronous signature request information And sends an asynchronous radio signal to the communication chip 105 of the fraudulent low-power medium to request an electronic signature value (605). According to an embodiment of the present invention, the mth MS 200 may transmit the asynchronous signature request information through an asynchronous radio signal by encrypting the asynchronous signature request information, It can be divided into t bit streams and transmitted.

The communication chip 105 of the low-power medium receives (610) an asynchronous radio signal corresponding to asynchronous signature request information including a session ID for identifying asynchronous short-range wireless communication with the m th terminal 200, And checks the asynchronous signature request information included in the asynchronous radio signal received from the m th terminal 200 (615). If the asynchronous signature request information included in the asynchronous radio signal for the connection request is encrypted, the communication chip 105 of the low-power medium can decrypt the encrypted asynchronous signature request information, and if the asynchronous signature request information includes t If the bitstream is divided and received, it can be restored.

The communication chip (105) of the low power medium having received the asynchronous radio signal including the asynchronous signature request information from the m th terminal (200) receives the asynchronous radio signal from the m th terminal (or restarts) the session ID for a specified period of time (620) and maintains the session ID for managing the asynchronous local area wireless communication with the m terminal 200, And an asynchronous local area wireless communication with the m th terminal 200 when the asynchronous radio signal is additionally received from the m th terminal 200 within a predetermined period of time The process of maintaining the ID for a predetermined period of time (or restarting after initializing the time) is repeated. However, The mobile terminal 200 may initiate connection approval for the m th terminal 200 and / or erase the session ID for the m th terminal 200 if an asynchronous radio signal is not additionally received from the m th terminal 200 .

Meanwhile, the communication chip 105 of the low-power medium which has confirmed the asynchronous signature request information received from the m th terminal 200 receives the asynchronous signature request information from the m th terminal 200, The electronic signature value is generated through the IC chip 150 of the low-power medium and checked to see if the digital signature value is provided to the communication chip 105 (625).

If the digital signature value is not generated at the time when the asynchronous signature request information is received from the m th MS 200 (for example, a digital signature value is not generated or a generation error is confirmed) The communication chip 105 of the low power medium generates asynchronous response information including a session ID with the m th terminal 200 and transmits the asynchronous response information to the m th terminal 200, (635), the communication chip (105) of the low-power medium can send out an asynchronous radio signal that does not specify the receiving side (635) according to an implementation method, whereby the communication chip (105) of the low- The digital signature value is not exposed to another terminal even if another terminal capable of transmitting and receiving the asynchronous radio signal exists in the vicinity of the mth terminal 200 in the short range communication range. Meanwhile, the m th terminal 200 receives (640) an asynchronous radio signal including the asynchronous response information from the communication chip 105 of the low-power medium, and checks whether the asynchronous response information includes an error code 645). If the asynchronous response information does not include an error code, the process of transmitting the asynchronous radio signal including the asynchronous signature request information is repeated a predetermined number of times or more (605), and the asynchronous response information includes an error code The error code may be output (650).

Meanwhile, if the digital signature value is generated at the time of receiving the asynchronous signature request information from the m th MS 200, the communication chip 105 of the low power medium generates a session ID with the m th MS 200 Generates asynchronous signature information including the generated digital signature value (655), and transmits an asynchronous radio signal including the asynchronous signature information to the m th terminal (660). According to an embodiment of the present invention, the communication chip 105 of the low-power medium may encrypt the asynchronous signature information and transmit it via an asynchronous radio signal, or may cause the asynchronous signature information to exceed n bits It can be divided into t bit streams and transmitted.

The m-th terminal 200 receives the asynchronous radio signal including the asynchronous signature information from the communication chip 105 of the low-power medium (665), and confirms the digital signature value included in the asynchronous signature information (670 ). If the asynchronous signature information included in the asynchronous radio signal for the connection request is encrypted, the m th terminal 200 can decrypt the encrypted asynchronous signature information. If the asynchronous signature information is divided into t bitstreams If so, you can restore it. The m-th terminal 200 performs an electronic signature-based authentication procedure using the verified digital signature value (675).

100: Low power medium 105: Communication chip
110: asynchronous radio processing unit 120: interface unit
130: information storage unit 132: signal transmission unit
134: signal receiving unit 136: connection acknowledgment unit
138: Session management unit 140: Generated information receiving unit
142: Signature processing unit 144: Request information receiving unit
146: signature verification unit 148: information transmission unit
150: IC chip 172:
174: Authentication processing unit 176:
178: Signature provider 180: Button section
200: terminal 220: short-range wireless communication unit
225: program 230: authentication value storage unit
235: encryption / decryption key storage unit 240: low power medium verification unit
245: connection request unit 250:
255: generation requesting unit 260: signature requesting unit
265: signature receiving unit 270: signature value checking unit
275: Authentication procedure section

Claims (18)

1. A method for executing via a chip of a low-power medium having one or more chips with an asynchronous local wireless communication function and a certificate-based electronic signature function,
A first step of storing authentication information for identifying and authenticating a predetermined terminal;
A second step of transmitting a radio signal that does not specify a receiving side based on the button operation on the one surface;
A third step of receiving a connection request from M (M? 1) terminals that have received the transmitted radio signal;
A fourth step of identifying and authenticating a predetermined m (1? M? M) terminal among the M terminals requested to be accessed using the authentication information to approve the connection;
Asynchronous signature generation information including specified information including a session ID for identifying asynchronous communication with the access authorized m terminal and a certificate PIN and signature target information required for generating a certificate based signature, A fifth step of receiving the data;
A sixth step of initiating a procedure for maintaining a session ID of the asynchronous signature generation information for a predetermined time and generating an electronic signature value while maintaining the session ID in order to identify asynchronous communication with the mth terminal;
A seventh step of receiving asynchronous signature request information including the session ID from the m &lt; th &gt; terminal and requesting provision of an electronic signature value generated based on the asynchronous signature generation information; And
If the digital signature value is not generated at the time of receiving the asynchronous signature request information from the mth terminal, transmits an asynchronous radio signal corresponding to the specified asynchronous response information, and receives the asynchronous signature request information from the mth terminal And transmitting the asynchronous radio signal corresponding to the asynchronous signature information including the session ID and the digital signature value to the mth terminal when the digital signature value is generated at a point in time,
Wherein the digital signature value is not provided in response to the asynchronous signature generation information,
If the asynchronous signature generation information is N (N &gt; n) bits exceeding the specified size n (n &gt; = 160)
Wherein the mth terminal divides the N-bit asynchronous signature generation information into k (k &lt; = (ni)) bit unit data including i (i? 1) (t &gt; = 2) bit streams, and asynchronously transmits t bit streams sequentially assigned sequence IDs to each bit stream, and the chip asynchronously receives t bit streams, Bit asynchronous signature generation information by combining the k-bit unit data included in the received t bitstreams, and restoring the N-bit asynchronous signature generation information.
The method of claim 1,
And an authentication value capable of authenticating a terminal installed and executing a specific application using the authentication information.
The method according to claim 1,
The first step may further include storing a key value for asynchronous secure communication with a predetermined terminal,
Wherein the asynchronous signature generation information is encrypted and decrypted through the key value and decrypted through the key value.
4. The method of claim 1 or 3, wherein the asynchronous signature generation information comprises:
And an APDU (Application Protocol Data Unit) command structure for the IC chip when the chip includes an IC chip.
delete The method according to claim 1,
(1 &lt; / = l &lt; = t) th bit stream among the t bit streams to be received, and if the first bit stream that has not been received effectively is identified, And transmits the stream request information requesting the first bitstream or the entire bitstream not including the session ID, to receive the first bitstream. The asynchronous short-range wireless communication-based digital signature Way.
The method according to claim 1,
Wherein the m &lt; th &gt; terminal repeatedly transmits the t bit streams for a predetermined number of times or more,
The chip checks a first bit stream (1 &lt; = l &lt; th &gt;) bit stream that is not effectively received among the t bit streams to be received. Wherein the first bitstream is validly received in the receiving step.
The apparatus of claim 1, wherein the k-
and a session ID of j (j? 1) bits.
The apparatus of claim 1, wherein the low-
And a chip having an asynchronous local area wireless communication function and a certificate-based electronic signature function integrated with the asynchronous local area wireless communication.
The apparatus of claim 1, wherein the low-
A first chip having an asynchronous local wireless communication function and a second chip having a certificate based electronic signature function,
Wherein the first chip communicates with the second chip in the low power medium.
11. The method of claim 10,
When the second chip includes an IC chip,
Wherein the first chip initiates a procedure for receiving asynchronous signature generation information including an APDU command structure from the mth terminal and injecting an APDU command into the IC chip to generate a digital signature value, And establishing an APDU command based on the received asynchronous signature generation information and injecting the APDU command into the IC chip to generate an electronic signature value.
The mobile communication terminal according to claim 1,
After transmitting a radio signal including the asynchronous signature generation information, a radio signal including the asynchronous signature request information is transmitted after waiting a predetermined time to generate an electronic signature value in the chip of the low-power medium A method for implementing an asynchronous local wireless communication based digital signature.
The method according to claim 1,
The first step may further include storing a key value for asynchronous secure communication with a predetermined terminal,
Wherein the asynchronous signature information is encrypted so as to be decrypted through the mth terminal using the key value, and the asynchronous signature information is transmitted.
14. The method of claim 1 or 13,
And an APDU response structure for the IC chip when the chip includes an IC chip.
The method according to claim 1,
If the asynchronous signature information is N (N > n) bits exceeding the specified size n (n &gt; = 160)
Wherein the chip divides the N-bit asynchronous signature information into k (k &lt; = (ni)) bit unit data capable of including i (i? 1) bit sequence IDs, &Gt; = 2) bitstreams and simultaneously transmits t bitstreams sequentially assigned sequence IDs to each bitstream, asynchronously,
Wherein the mth terminal asynchronously receives t bitstreams and then combines the k bit unit data included in the received t bitstreams based on the sequence ID to recover N bit asynchronous signature information Based short-range wireless communication based digital signature.
16. The method of claim 15,
The apparatus of claim 1, wherein the mth terminal checks a first (1 &lt; = l &lt; th &gt;) th bit stream that is not validly received among the t bit streams to be received, And transmits the stream request information requesting the first bitstream or the entire bitstream not including the session ID to the chip of the asynchronous local wireless communication system A method for implementing an electronic signature.
16. The method of claim 15,
Wherein the chip repeatedly transmits the t bit streams over a specified number of times,
Wherein the mth terminal checks a first bit stream (1 &lt; = l &lt; th &gt;) bit stream that is not validly received among the t bit streams to be received, Wherein the first bitstream is validly received in a receiving step of the asynchronous local area wireless communication.
The method according to claim 1,
When an asynchronous radio signal including the session ID is not received from the mth terminal for a predetermined time or more while maintaining a session ID for identifying asynchronous communication with the access authorized m terminal, ID of the asynchronous short range wireless communication based electronic signature.

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