KR20150004955A - Method for Providing Authentication Code by using End-To-End Authentication between USIM and Server - Google Patents

Abstract

The present invention relates to a method of providing a server type authentication code using end-to-end authentication between a universal subscriber identity module (USIM) and a server. The method of providing a server type authentication code using end-to-end authentication between a USIM and a server according to the present invention is a method of providing a server type authentication code using end-to-end authentication between a USIM and a server executed on a chip in of the USIM which interfaces with a wireless terminal comprising: a first step of receiving a time value from the interfaced wireless terminal; a second step of generating encryption data (c) by encrypting data (c) including the time value; a third step of providing the generated encryption data (c) to the interfaced wireless terminal, wherein the encryption data (c) is transmitted to a server through the wireless terminal; a fourth step of receiving encryption data (s), which is generated by encrypting data (s) including a server side random number code dynamically generated by the server, through the interfaced wireless terminal; a fifth step of acknowledging the server side random number from the data (s) decrypted from the encryption data (s); and a sixth step of providing an authentication code corresponding to the server side random number code to the interfaced wireless terminal.

Description

[0001] The present invention relates to a method for providing a server-type authentication code using an end-to-

The present invention identifies a one-time authentication code dynamically generated by the server based on end-to-end authentication between a USIM and a server, and outputs the disposable authentication code through a wireless terminal interfaced with the USIM.

In order for a disposable authentication code called OTP (One Time Password) to be used for payment settlement or financial transactions, it is necessary to establish the condition of "separation of media" in Article 34. (2). Currently, the Financial Supervisory Service (FSS) determines which method meets the conditions for media separation. Currently, the method that is recognized as such media separation is to use OTP dynamically generated through a sealed OTP generator or OTP card for financial transactions Only the method of inputting to the terminal is recognized as the media separation.

However, the conventional method of recognizing media separation is inconvenient because a user must possess an OTP-based authentication medium such as an OTP generator or an OTP card. In addition, in order to produce such an OTP-based authentication medium, There is a problem that an error due to erroneous input frequently occurs in the process of inputting the OTP dynamically generated through the OTP generator or the OTP card to the terminal.

In order to solve the above problems, an object of the present invention is to provide a radio communication system, in which a USIM equipped with an encryption / decryption function communicates with a designated server via a radio terminal to check a server- And a server-type authentication code providing method using an end-to-end authentication between a USIM and a server that processes an authentication code corresponding to a random number code to be outputted through the wireless terminal.

A method for providing a server-type authentication code using an end-to-end authentication between a USIM and a server according to the present invention is a method for providing a server-type authentication code using an end-to-end authentication between a USIM (Universal Subscriber Identity Module) A method for providing a type authentication code, comprising the steps of: receiving a time value from an interfaced wireless terminal; generating cipher data (c) obtained by encrypting data (c) including the time value; A third step of providing the generated encryption data c to the interfaced wireless terminal; the encryption data c is transmitted to the server through the wireless terminal; and the server side random number code dynamically generated by the server (S) decrypted with the encrypted data (s) via the interfaced wireless terminal; and a fourth step of receiving encrypted data (s) And a sixth step of providing an authentication code from the fifth step to determine the code corresponding to the random number code by the server-side interface of the wireless terminal.

According to the present invention, the data (c) may further include a designated unique code. The data (c) may further include a chip-side random number value. The data (c) may further include a designated key value (1).

According to the present invention, the encrypted data (c) can be transmitted to a server designated by the wireless terminal and decrypted.

According to the present invention, a method of providing a server-type authentication code using end-to-end authentication between the USIM and a server may further include processing a specified authentication procedure to provide the authentication code to the interfaced wireless terminal .

According to the present invention, the data (s) further includes a MAC (Message Authentication Code) generated through the server, and the server type authentication code providing method using end-to-end authentication between the USIM and the server, A step 5-1 of generating a key value 2 by encrypting the random number and the key value 1 with a designated cipher system and encrypting the random number code and the key value 2 with the designated cipher system to generate a key value 3 A step 5-2 of generating a MAC by encrypting the chip-side random number and the key value (3) with a designated cipher system, and generating the MAC by using the generated decrypted data and authenticating the MAC identified by the MAC (s).

According to the present invention, the sixth step may provide an authentication code corresponding to the identified random number code to the wireless terminal when the MAC identified from the decrypted data (s) is authenticated.

According to the present invention, the authentication code may include at least one of a server-side random number code, a partial code of the server-side random number code, and a code generated by processing the server-side random number code.

A method for providing a server-type authentication code using an end-to-end authentication between a USIM and a server according to the present invention comprises the steps of: terminating a USIM carried out through a server communicating with a wireless terminal interfaced with a chip of a Universal Subscriber Identity Module (USIM) (C), which is obtained by encrypting data (c) including the time value provided by the wireless terminal to the chip of the USIM through a cryptographic module of the chip, is received A second step of decrypting the received encrypted data (c) through a designated decryption method to confirm a time value, a step of storing the confirmed time value, A third step of checking the side random number code, and encrypting the data (s) including the server side random number code so as to be decodable through a decoding module provided in the chip of the USIM And a fifth step of transmitting the generated encrypted data (s) to the wireless terminal, wherein the encrypted data (s) is transmitted from the wireless terminal to the chip of the USIM And is decrypted through the decryption module of the chip, and an authentication code corresponding to the server side random number code can be provided to the wireless terminal.

According to the present invention, the data (c) may further include a designated unique code. The data (c) may further include a chip-side random number value. The data (c) may further include a designated key value (1).

According to the present invention, the second step may further include checking a unique code from the decoded data (c).

According to another aspect of the present invention, there is provided a method of providing a server-type authentication code using end-to-end authentication between a USIM and a server, the method including storing a unique code assigned to a chip of the USIM on a storage medium, Checking the unique code from the decrypted data (c), and authenticating the USIM by comparing the authenticated unique code with the stored unique code.

According to the present invention, the second step may further include checking a chip-side random number value from the decrypted data (c). The second step may further include checking the key value (1) from the decrypted data (c).

According to the present invention, the third step may dynamically generate the random number code through the designated code generation rule or the random number code generated dynamically through the designated code generation server.

According to the present invention, a method of providing a server-type authentication code using end-to-end authentication between the USIM and a server comprises: encrypting a chip-side random number value and a key value (1) identified from the decrypted data (c) A third step (3-1) of generating a key value (2) by encrypting the server side random number code and a key value (2) with a designated cipher method to generate a key value (3) And a third step of generating MAC (Message Authentication Code) by encrypting the chip-side random number value and the key value (3) with a designated cipher method, wherein the fourth step includes: 1). The designated cipher system may include a cipher system that matches the cipher system of the cipher module of the chip.

According to the present invention, a USIM interfaced with a wireless terminal performs end-to-end authentication with a designated server via the wireless terminal to mutually authenticate the USIM and a server, and a server side And outputs a disposable authentication code corresponding to the random number code through the wireless terminal, thereby providing a condition for medium separation and providing a disposable authentication code service that is safer, more convenient, and less expensive than the conventional OTP authentication.

1 is a diagram showing a configuration of a USIM according to an embodiment of the present invention.
2 is a diagram illustrating a functional configuration of a wireless terminal that interfaces with a USIM according to an embodiment of the present invention.
3 is a diagram showing a configuration of a server according to an embodiment of the present invention.
4 illustrates an end-to-end authentication process in which a server authenticates a USIM according to an embodiment of the present invention.
FIG. 5 illustrates an end-to-end authentication process in which a USIM authenticates a server according to an embodiment of the present invention.
FIG. 6 illustrates a process of providing an authentication code 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. For example, it is possible that a configuration provided on the server side is implemented on the terminal side, or conversely, a configuration portion provided on the terminal side is implemented on the server side.

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 USIM 100 according to an embodiment of the present invention.

1 shows a USIM (Universal Subscriber Identity Module) 100 equipped with an encryption / decryption function communicating with a designated server 300 via a wireless terminal 200, Side random number code and processes the authentication code corresponding to the server-side random number code to be output through the wireless terminal 200. The present invention is not limited to the above- Those skilled in the art will be able to refer to and / or modify the FIGURE 1 to illustrate various implementations of the configuration of the USIM 100 (e.g., some of the components may be omitted, or fragmented, or combined) However, the present invention is not limited to the above-described embodiments, and the technical features of the present invention are not limited only by the method shown in FIG.

The USIM 100 according to the present invention is a generic name of a chip card conforming to the UICC standard including the ISO / IEC 7816 standard, preferably mounted on or detached from the wireless terminal 200, Respectively. For example, the USIM 100 may have an encryption / decryption function according to a financial IC card standard. In FIG. 1, for the sake of convenience, the functional configuration (for example, a communication-related function configuration, etc.) basically provided in the USIM 100 will not be described in detail.

1, the USIM 100 includes a contact point 170 (for example, a COB (Chip On Board)) that contacts the USIM reader unit 209 of the wireless terminal 200 in a contact manner, An interface unit 160 for interfacing with the wireless terminal 200 via the wireless terminal 200 and an interface unit 160 for processing the encryption decryption function and communicating with the designated server 300 via the wireless terminal 200, Side random number code and outputting the authentication code corresponding to the server-side random number code through the wireless terminal 200, and a control unit 110 for controlling at least the control of the control unit 110 A chip 105 integrated with a configuration corresponding to a memory unit 165 for storing one program code or data set is mounted.

The memory unit 165 is a general term of a nonvolatile memory corresponding to a storage resource of the chip 105. The memory unit 165 preferably includes a read only memory (ROM), an electrically erasable and programmable read only memory (EEPROM) And the like. Preferably, the memory unit 165 includes both a NAND-type memory and a NOR-type memory. And may be included in the category of the memory unit 165 as a RAM (Random Access Memory) provided in the chip 105 according to an implementation method. According to an embodiment of the present invention, the memory unit 165 stores program codes corresponding to COS (Chip Operating System), and program codes corresponding to applets corresponding to services to be provided through the USIM 100 .

The control unit 110 is a collective term for controlling the operation of the chip 105. The control unit 110 preferably controls the operation of one or more of a central processing unit (CPU), a micro processing unit (MPU), and a coprocessor Lt; / RTI > According to the embodiment of the present invention, the controller 110 may define a state in which the program code corresponding to the COS recorded in the memory unit 165 is loaded into the execution memory and operated by the processor, FIG. 5 is a diagram showing a configuration of a function implemented through a program code for providing an end-to-end authentication-based server-type authentication code service between the USIM 100 and the server 300 according to the present invention among program codes corresponding to applets operating on the server 1, respectively.

According to an embodiment of the present invention, the control unit 110 includes a cryptographic module 115 for encrypting one or more values through a specified cryptographic algorithm (for example, SEED, DEA, IDEA, DES, etc.) And a decryption module 120 for decrypting the decrypted data. The cryptographic module 115 and the decryption module 120 may be implemented as separate modules or as one module.

The cryptographic module 115 and the decryption module 120 may be implemented in the form of a logical circuit using the coprocessor or in the form of a program code on a COS or a program code It is clear that the present invention is not limited by the manner in which the cryptographic module 115 and the decryption module 120 are implemented in the chip 105. [

1, a chip 105 of the USIM 100 includes an information receiving unit 125 that receives a designated input value from an interfaced wireless terminal 200, and a data c that includes the input value An encryption processing unit 130 for generating cipher data c decryptably encrypted in a designated server 300 through a designated cipher module 115 and a cipher unit 130 for encrypting the generated cipher data c to the interfaced wireless terminal 200 The authentication processing unit 145 processes the authentication specified for the end-to-end authentication-based server-type authentication code service.

When the USIM 100 is interfaced with the wireless terminal 200, the information receiving unit 125 receives a designated input value from the interfaced wireless terminal 200. The input values are collectively referred to as values to be input from the wireless terminal 200 for the end-to-end authentication-based server-type authentication code service, preferably a time that is matched with the international time obtained through the timer of the wireless terminal 200 Value. However, the input value is not limited to the time value, and may be any value as long as it is a value designated to be input from the wireless terminal 200 for the end-to-end authentication-based server type authentication code service. According to an embodiment of the present invention, the input value includes at least one of a terminal side random number value generated in the wireless terminal 200 and a challenge value generated through the server 300 communicating with the wireless terminal 200 can do. Hereinafter, the characteristics of the present invention will be described by considering the input value as a time value for convenience.

The encryption processing unit 130 constitutes data c including the time value and encrypts the data c so that it can be decrypted by the designated server 300 through the designated cryptographic module 115 to generate encrypted data c ). Preferably, the time value may perform a function of a time stamp of the cipher data c.

According to the first chip-side extended cryptosystem of the present invention, the data (c) may further include a unique code designated in the chip 105, and the cryptographic processor 130 may include the time value and the unique code (C) through the encryption module 115 to generate the encrypted data (c). The unique code is a generic name of a code unique to the chip 105 of each USIM 100. The unique code includes a card serial number or a chip serial number (CSN) stored in a designated unique area of the chip 105, The area in which the applet is recorded).

According to the second chip-side extended cryptosystem of the present invention, the data (c) may further include a chip-side random number designated in the chip 105 or specified in real time, and the cryptographic processor 130 (C) including the time value and the chip side random number value may be encrypted through the cryptographic module 115 to generate the cryptographic data (c). The chip-side random number value may include a random number value generated in a random number form in the chip 105 and stored in a designated storage area, or the random number generated in real time (e.g., 16 bytes CN (Card Random), etc.).

According to the third chip-side extended cryptosystem of the present invention, the data (c) may further include a key value (1) designated in the chip 105, and the cryptographic processor (130) (C) including the value (1) can be encrypted through the cryptographic module (115) to generate encrypted data (c). The key value 1 is a key value injected into the chip 105 at the time of issuing the USIM 100, a key value injected into the memory of the chip 105 at the time of issuing the applet, The key value may include at least one of the key values injected so as to be recorded in the memory.

According to the fourth chip-side extended cipher system of the present invention, the data (c) includes at least one of the time value, the unique code of the first to third chip-side extended cipher systems, the chip- (C) including at least one or more of the time value, the unique code, the chip-side random number, and the key value (1), and the encryption processing unit It is possible to generate the encrypted data c by encrypting it through the encryption module 115. [ According to the extension scheme of the present invention, the data (c) may further include information other than the information included in the first to fourth chip-side extended cipher schemes according to the intention of a person skilled in the art. It is clear that all embodiments are included.

The data transmitting unit 135 provides the encrypted data c generated through the encryption processing unit 130 to the interfaced wireless terminal 200. The wireless terminal 200 transmits the encrypted data c via the designated communication network, (c) to the designated server 300. At this time, since the encrypted data (c) is encrypted so as to be decryptable through the designated server (300), the wireless terminal (200) can not decrypt the encrypted data (c).

According to an embodiment of the present invention, the wireless terminal 200 may encrypt the cipher data c according to a security protocol with the server 300, and the designated server 300 may transmit the encrypted data c to the wireless terminal 200 (C) encrypted by the cryptographic process unit (c).

According to the embodiment of the present invention, the wireless terminal 200 may transmit the cipher data c to the designated server 300 at a designated time point before or after transmission of the ciphered data c, And may transmit the terminal identification value to the designated server 300. The terminal identification value is a value indicating whether or not the server 200 has been authenticated by the server 300 in order to uniquely identify the wireless terminal 200 at the time when the program 215 for the end- The information stored in the read area of the wireless terminal 200, the information stored in the unique storage area of the wireless terminal 200, the H / W of the wireless terminal 200, Information assigned to the network 215 to which the wireless terminal 200 is connected, information assigned to the program 215 for the end-to-end authentication-based server-type authentication code service, And may include at least one piece of information stored in the wireless terminal 200.

Meanwhile, the authentication processing unit 145 receives the time value from the wireless terminal 200 at the time of interfacing with the wireless terminal 200 and, at a designated time during the process of improving the password data c, Type authentication code service. Preferably, the designated authentication may include PIN (Personal Identification Number) authentication. The authentication processing unit 145 stores a PIN authentication value for PIN authentication, receives a PIN value from the interfaced wireless terminal 200, and can authenticate the received PIN value using the PIN authentication value . For example, the PIN value may be received and authenticated before the time value is received, or received and authenticated with the time value. According to an embodiment of the present invention, the time when the authentication is processed may be performed before the authentication code is provided from the chip 105 of the USIM 100 to the wireless terminal 200, and thus the present invention is not limited thereto. The authentication process may be omitted according to the intention of those skilled in the art.

The server 300 receiving the encrypted data (c) decrypts the encrypted data (c) according to the specified decryption procedure, and performs a procedure such as authentication, verification, and registration for the decrypted data (c) . Preferably, the server 300 verifies the unique code included in the decrypted data (c), and transmits the corresponding unique code to the server 300, It is possible to perform a procedure for comparing and authenticating with the unique code of the USIM 100. [ Alternatively, the server 300 may check the time value included in the decrypted data (c), and the server 300 may determine whether the determined time value is designated based on the internal time (= time synchronized with the International Standard Time) It is possible to verify whether the time is within a timeout (for example, within 2 seconds or the like). Alternatively, the server 300 may register the time value identified from the decrypted data (c) in a storage medium designated as a time stamp.

The server 300 dynamically generates a server-side random number code according to a designated code generation rule or a dynamically generated random number code through the designated code generation server 370 as the server-side random number code. The server 300 decrypts the data s including the server side random number code so as to be decryptable through the decryption module 120 of the chip 105 to generate encrypted data s, 200). The encrypted data s may further include a MAC (Message Authentication Code) generated according to a designated procedure and / or a key value (1) included in the encrypted data (c).

1, a chip 105 of the USIM 100 encrypts encrypted data (s) obtained by encrypting data (s) including a server-side random number code dynamically generated by the server 300, A decryption processing unit 150 for checking the server side random number code from the data s decrypted through the specified decryption module 120, And a code providing unit (155) for providing an authentication code corresponding to the server-side random number code to the interfaced wireless terminal (200), and providing the authentication code to the interfaced wireless terminal (200) And an authentication processing unit 145 for processing the authentication specified for the authentication.

The wireless terminal 200 may generate dynamically generated data dynamically generated by the server 300 or encrypted data (s) including the server-side random number code supplied from the designated code generation server 370 s and sends the encrypted data s to the chip 105 of the USIM 100. The data receiving unit 140 receives the encrypted data s from the interfacing wireless terminal 200 by the server 300 And receives the encrypted data (s) obtained by encrypting the data (s) including the dynamically generated server side random number code. The cipher data (s) according to an exemplary embodiment of the present invention will be described as an embodiment of FIG. 1 until a MAC generated at the server side is further processed to perform a MAC authentication procedure.

The decryption processing unit 150 performs a procedure for decrypting the received encrypted data s through the designated decryption module 120 and verifies the decrypted data s through the decryption module 120. [

According to an embodiment of the present invention, the decrypted data s may further include a MAC and / or a key value (1) generated on the server side. When the decrypted data s includes a MAC, The authentication processing unit 145 may perform a procedure of authenticating a MAC included in the decrypted data s through a MAC creation procedure matched with the procedure of generating the MAC in the server 300. [

According to the embodiment of the present invention, when the decrypted data s includes a MAC, the authentication processing unit 145 encrypts the chip-side random number value and the key value (1) through the designated cryptographic module 115 Generates a key value (2), encrypts a server-side random number code included in the decrypted data (s) and the generated key value (2) to generate a key value (3) And generating the MAC by encrypting the generated key value (3), and then comparing the generated MAC with the MAC included in the decrypted data (s) to determine the validity of the MAC included in the decrypted data (s) Can be authenticated. Preferably, the validity authentication of the MAC authenticates the validity of the server 300 that generated the server-side random number code in the chip 105 of the USIM 100. [

If the decrypted data s includes the key value 1, the authentication processing unit 145 adds the key value 1 included in the data c and the key value 1 to the decrypted data s. (1) to verify the validity of the key value (1) in the decrypted data (s). Preferably, validity authentication of the key value (1) authenticates the validity of the server (300) that generated the server side random number code in the chip (105) of the USIM (100).

When the decrypted data s is confirmed through the decryption processing unit 150 or the MAC included in the decrypted data s is authenticated through the authentication processing unit 145, The code providing unit 155 confirms the server side random number code included in the decrypted data s and determines the one time use authentication code corresponding to the server side random number code.

According to the first authentication code determination method of the present invention, the code providing unit 155 can directly determine the server side random number code included in the decrypted data (s) as an authentication code.

According to the second authentication code determination method of the present invention, the code providing unit 155 may determine a partial code of the server side random number code included in the decrypted data (s) to be a predetermined number of digits of the authentication code. For example, if the server-side random number code is a 16-byte code, the code providing unit 155 may determine the first 8-byte code of the 16-byte code as an authentication code or the 6-byte code It can be determined by the authentication code, or the latter 7 byte code can be determined as the authentication code. Alternatively, nibble or byte at the specified position can be selectively extracted and determined as an authentication code. If there is a padding region in the server-side random number code, it is preferable that the padding region is not included in some code corresponding to the authentication code.

According to the third authentication code determination method of the present invention, the code providing unit 155 can determine the code generated by processing the server-side random number code to be the authentication code of the designated digit. For example, the authentication code may include a code obtained by hashing the server-side random number code with a specified hash algorithm. Alternatively, the authentication code may be generated by using the server-side random number code in accordance with a specified code generation rule (e.g., a rule for using a hash algorithm for generating a code of a predetermined number of digits and using at least one seed provided in the chip 105) Lt; RTI ID = 0.0 > code. ≪ / RTI > Alternatively, the authentication code may include a code dynamically generated using the time value as a seed of a designated code generation rule. Alternatively, the authentication code may include a dynamically generated code using the time value and the server-side random number code as a seed of the designated code generation rule.

According to the fourth authentication code determination method of the present invention, the code providing unit 155 can determine N (N? 2) digit authentication codes by combining the first to third authentication code determination methods. For example, the code providing unit 155 may configure a code of (1? N <N) digits among the N-digit authentication codes according to the second authentication code determination method, Nn) digits, and then the N-digit code and the (Nn) code are combined to determine an N-digit verification code.

The code providing unit 155 provides the interfaced wireless terminal 200 with an authentication code determined through at least one of the first through fourth authentication code determination methods. The wireless terminal 200 is input through a designated transaction terminal (for example, the wireless terminal 200 or another terminal other than the wireless terminal 200) by outputting the received authentication code, Or the received authentication code may be transmitted to a specified authentication server so that the received authentication code can be used as an authentication means.

2 is a functional block diagram of a wireless terminal 200 that interfaces with a USIM 100 according to an embodiment of the present invention.

2 shows a configuration of a wireless terminal 200 interfacing with a chip 105 of the USIM 100 shown in FIG. 1 and a functional configuration of a program 215 operating in the wireless terminal 200 Those skilled in the art will be able to refer to and / or modify the FIG. 2 to various implementations of the functional configuration of the wireless terminal 200, 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. The wireless terminal 200 of the present invention is a collective term of all terminals that interface with the USIM 100 and preferably includes at least one smart phone, a tablet PC, a mobile phone, and the like.

2, the wireless terminal 200 includes a control unit 201, a memory unit 210, a screen output unit 202, a key input unit 203, a sound processing unit 204, a wireless network communication unit 208, A near field wireless communication unit 207, a proximity wireless communication unit 205, a USIM reader unit 209, and a USIM 100, and has a battery 206 for power supply.

The control unit 201 is a general term for controlling the operation of the wireless terminal 200. The control unit 201 includes at least one processor and an execution memory, BUS). According to the present invention, the control unit 201 loads at least one program code included in the wireless terminal 200 into the execution memory through the processor, and outputs the result through at least one configuration And controls the operation of the wireless terminal 200. Hereinafter, the configuration of the program 215 of the present invention, which is implemented in the form of program code for convenience, will be described in the control unit 201. FIG.

The memory unit 210 is a general term of a nonvolatile memory corresponding to a storage resource of the wireless terminal 200 and includes at least one program code executed through the control unit 201 and at least one Save and maintain the dataset. The memory unit 210 basically includes a system program code and a system data set corresponding to the operating system of the wireless terminal 200, a communication program code and a communication data set for processing a wireless communication connection of the wireless terminal 200, The program code and the data set corresponding to the program 215 of the present invention are also stored in the memory unit 210. In addition,

The screen output unit 202 is composed of a screen output device (e.g., an LCD (Liquid Crystal Display) corresponding to the output resource of the wireless terminal 200 and a driving module for driving the screen output device. And outputs the calculation result corresponding to the screen output among the various calculation results of the control unit 201 to the screen output device.

The key input unit 203 may include at least one user input device corresponding to the input resource of the wireless terminal 200 (e.g., a button, a keypad, a touch pad, a touch screen interlocked with the screen output unit 202) And inputs a command for instructing various operations of the control unit 201 in cooperation with the control unit 201 or inputs data necessary for the operation of the control unit 201. [

The sound processing unit 204 is composed of a speaker corresponding to the output resource of the wireless terminal 200, a microphone corresponding to the input resource of the wireless terminal 200 and a driving module for driving the microphone, And outputs the operation result corresponding to the sound output among the various calculation results of the control unit 201 through the speaker or transmits the sound data inputted through the microphone to the control unit 201. [ The driving module decodes sound data to be outputted through the speaker and converts the sound data into a sound signal or encodes the sound signal inputted through the microphone to encode the sound signal.

The proximity wireless communication unit 205 is a communication unit that processes one or more proximity wireless communication among a bidirectional 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 (for example, As a collective term of resources, it is possible to process the proximity wireless communication according to the NFC (Near Field Communication) standard of the 13.56 Mz frequency band. Alternatively, the proximity wireless communication unit 205 may process proximity wireless communication of the ISO 18000 series standard, and in this case, it may process proximity wireless communication for a frequency band other than the 13.56 Mz frequency band. For example, the proximity wireless communication unit 205 can operate in a reader mode, a tag mode, or a bidirectional communication mode. Meanwhile, the proximity wireless communication unit 205 may be included in a communication resource for connecting the wireless terminal 200 to a communication network according to an object to be communicated nearby.

The wireless network communication unit 208 and the short-range wireless communication unit 207 are collectively referred to as communication resources for connecting the wireless terminal 200 to a designated communication network. Preferably, the wireless terminal 200 may include a wireless network communication unit 208 as a basic communication resource, and may include one or more short-range wireless communication units 207.

The wireless network communication unit 208 is a collective term for communication resources for connecting the wireless 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 at least one processing module connected to the control unit 201. The control unit 201 transmits the calculation result corresponding to the wireless communication among the various calculation results of the control unit 201 through the wireless communication network or receives data through the wireless communication network To the control unit 201, and performs the connection, registration, communication, and handoff procedures of the wireless communication. According to the present invention, the wireless network communication unit 208 can connect the wireless terminal 200 to a telephone communication network including a communication channel and a data channel via the exchange, and in some cases, May be connected to a data network providing communication-based wireless network data communication (e.g., the Internet).

According to an embodiment of the present invention, the wireless network communication unit 208 is a mobile communication unit that performs at least one of connection to a mobile communication network, location registration, call processing, call connection, data communication, and handoff 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 208 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 208. [ That is, the wireless network communication unit 208 is a collective term for a constituent unit connected to a wireless communication network through a cell-based base station irrespective of a frequency band of a wireless section, a type of a communication network, or a protocol.

The short-range wireless communication unit 207 is a collective term for communication resources connecting a communication session using a radio frequency signal within a predetermined distance (for example, 10 m) as a communication medium and connecting the wireless terminal 200 to the communication network based on the communication session , The wireless terminal 200 may be connected to the communication network through at least one of Wi-Fi communication, Bluetooth communication, public wireless communication, and UWB. According to an embodiment of the present invention, the short range wireless communication unit 207 may be integrated with or separated from the wireless network communication unit 208. According to the present invention, the short-distance wireless communication unit 207 connects the wireless terminal 200 to a data network providing packet-based short-range wireless data communication through a wireless AP.

The USIM reader unit 209 is a generic term of a configuration for exchanging at least one data set with a universal subscriber identity module that is mounted or detached from the mobile station 200 based on the ISO / IEC 7816 standard , And the data set is exchanged in a half duplex communication manner through an APDU (Application Protocol Data Unit).

The program 215 of the present invention is downloaded from a program providing server (for example, an Apple App Store or the like) through a data network to which the communication resource can be connected and is stored in the memory unit 210. The downloaded program 215 operates in conjunction with the designated server 300 and can be manually driven by a user or activated (or activated) after user confirmation or automatically by receiving a message. Meanwhile, a separate program 215 may be in operation for activating the program 215 after user confirmation or automatically, and thus the present invention is not limited thereto.

Referring to FIG. 2, a program 215 of the wireless terminal 200 accesses a designated server 300 through a data network to which the communication resource is connectable, thereby joining a user as a member, An authentication procedure unit 225 for performing a procedure for authenticating the validity of the program 215 through at least one communication network connectable through the communication resource, And an identification value registration unit 230 for registering terminal identification values provided or assigned to the server 200 in the designated server 300. At least one component of the membership subscription / authentication unit 220, the authentication procedure unit 225, and the identification value registration unit 230 may be omitted according to the embodiment.

The program 215 includes communication connection macro information for connecting to a designated server 300 via a data network to which the communication resource is connectable. The membership subscription / authentication unit 220 receives the screen output unit 202 (E.g., name, resident registration number, etc.) and an interface for inputting a member account through the data network, and transmits user information and user account information input through the interface to the designated server 300 through the data network And registers the user as a member.

Meanwhile, the subscription of the user can be subscribed through a separate user terminal other than the mobile terminal 200. Therefore, when the user is already registered as a member or is registered as a member through the user terminal, the membership registration / authentication unit 220 outputs an interface for inputting the user's member account, Transmits the member account input through the interface to the designated server 300 to authenticate the user as a member.

The authentication procedure unit 225 authenticates the validity of the program 215 to the designated server 300 through at least one communication network among the data network and the telephone communication network to which the communication resource is connectable. According to the embodiment of the present invention, the process of authenticating the validity of the program 215 is performed by performing an encryption / decryption communication process previously agreed upon between the program 215 and the designated server 300. For the sake of convenience, A detailed description of the process will be omitted.

According to the first program authentication method of the present invention, the program 215 can be downloaded through the program providing server in a state in which a unique value identifying the program operated by the designated server 300 is set. In this case, the authentication procedure unit 225 transmits the eigenvalue to the designated server 300 or performs a key exchange procedure according to the specified server 300 and the designated key exchange protocol based on the eigenvalue, It is possible to authenticate that the program 215 is a program operated by the specified server 300.

According to the second program authentication method of the present invention, the program 215 is downloaded via the program providing server, and is then downloaded to the computer via a token value (e.g., A device token assigned by the APNS, etc.) may be assigned. In this case, the authentication procedure unit 225 can authenticate that the program 215 is a program operated by the designated server 300 by transmitting the token value to the designated server 300 according to the designated path.

According to the third program authentication method of the present invention, the program 215 configures hash information by hashing at least one file corresponding to the program 215 according to a specified hash algorithm, 300 to authenticate that the program 215 is a valid program operated by the designated server 300. [ Meanwhile, the authentication procedure unit 225 may construct the hash information by using the key value internally determined or exchanged with the designated server 300 in the process of constructing the hash information.

According to the fourth program authentication method of the present invention, the program 215 is downloaded through a program providing server in a state in which a certificate for performing a specified authentication procedure is loaded, or after being downloaded through a program providing server, Certificates can be loaded according to roaming procedures. In this case, the authentication procedure unit 225 may selectively use the key exchange protocol and the encryption / decryption rule, the at least one key value set in the certificate according to the authentication procedure defined in the certificate, It is possible to verify that the program is operated by the control unit 300. The certificate may comprise at least one of a certificate of a designated server 300 or a certificate of a user using the program 215.

According to the fifth program authentication method of the present invention, when the authentication number transmitted from the server 300 specified through the message exchange protocol of the telephone network is received, the wireless terminal 200 receives the received authentication number, It is possible to authenticate that the program 215 is a program operated by the designated server 300 by transmitting the program 215 to the designated server 300 through the data network.

According to the sixth program authentication method of the present invention, the authentication procedure unit 225 receives the program 215 from the designated server 300 through an authentication method selectively combining at least one of the first through fifth program authentication methods ) Can be authenticated, and thus the present invention is not limited thereto.

The authentication procedure unit 225 may determine whether the wireless terminal 200 is connected to the memory unit 210 or SE (Secure Element, wireless) of the wireless terminal 200 at any specified time point before, A security storage area of at least one of a USIM (Universal Subscriber Identify Module) 100, an integrated circuit (IC) chip and a built-in chip of an external memory (e.g., SD memory) mounted or detached from the terminal 200 Unique information, or unique information allocated by the communication-end-side resource in the process of connecting or holding the wireless terminal 200 to the communication network specified through the wireless network communication unit 208, to the designated server 300, It is possible to simultaneously authenticate that the program 215 is a program operated by the designated server 300 and that the program 215 is running on the wireless terminal 200. [

The identification value registration unit 230 registers information stored in the reading area of the wireless terminal 200, information stored in the unique storage area of the wireless terminal 200, information recorded in the H / W configuration of the wireless terminal 200 , A terminal identification value including at least one of information assigned / assigned in the network to which the wireless terminal 200 is connected, and / or a program authentication process or authentication performed through the first to sixth program authentication methods As a result, it is possible to identify the terminal identification value including at least one of the information allocated to the program 215 and the information stored in the wireless terminal 200 by the program 215, To the designated server 300 and registers it.

Referring to FIG. 2, the program 215 of the wireless terminal 200 includes a program 215 of the USIM 100 for end-to-end authentication between the chip 105 of the USIM 100 and the designated server 300 A chip interlocking unit 235 interlocked with the chip 105 and a server interlocking with the server 300 through a communication network for end-to-end authentication between the chip 105 of the USIM 100 and the server 300 And a code verifying unit 240 for verifying an authentication code provided from the chip 105 of the USIM 100 as a result of end-to-end authentication between the chip 105 of the USIM 100 and the server 300. [ And a code output unit (250) for outputting the verified code, and a code transmission unit (255) for transmitting the verified code to a specified authentication server.

The chip interlocking unit 235 may be configured to transmit the authentication code provided from the chip 105 of the USIM 100 as a result of the end-to-end authentication between the chip 105 of the USIM 100 and the server 300 and the end- And the server interlock 240 is a general term for a program 215 that is interlocked with the chip 105 of the USIM 100 in order to use the server 100. The server interlock 240 is a generic term for a program 215 between the chip 105 of the USIM 100 and the server 300 Is a collective term for a program 215 component that interacts with the server 300 to utilize the authentication code provided from the chip 105 of the USIM 100 as a result of end-to-end authentication and end-to-end authentication.

The chip interlocking unit 235 is connected to the USIM 100 in order to receive an authentication code from the chip 105 of the USIM 100 based on end-to-end authentication between the chip 105 of the USIM 100 and the server 300, (105) of the chip (100). Preferably, the input value includes a time value obtained through a timer of the wireless terminal 200, and may include a terminal side random number value generated by the chip interlocking unit 235, &Lt; / RTI &gt; Hereinafter, the characteristics of the present invention will be described by considering the input value as a time value for convenience.

The chip interlocking unit 235 confirms the interfaced state of the chip 105 of the USIM 100 and provides the obtained time value to the chip 105 of the interfaced USIM 100. [ The chip 105 of the USIM 100 generates and provides cipher data c in which the data c containing the time value is decryptably decrypted by the designated server 300 through the designated cipher module 115 do. The chip interlocking unit 235 provides the cryptographic data c received from the chip 105 of the USIM 100 to the server interlocking unit 240.

According to the embodiment of the present invention, the chip interlocking unit 235 can perform the authentication procedure specified for the chip 105 of the USIM 100. [ The chip interlocking unit 235 receives the PIN value from the user and transmits the PIN value to the chip 105 of the interfaced USIM 100. In this case, . The chip 105 of the USIM 100 authenticates the PIN value. When the PIN authentication procedure is performed, the encrypted data (c) may be received from the chip 105 of the USIM 100 as a result of the PIN authentication. In the meantime, in accordance with the method of the present invention, the PIN authentication procedure is omitted or the password data (s) received from the server 300 is supplied to the chip 105 of the USIM 100, .

The server interworking unit 240 transmits the encryption data c to the server 300 using a communication protocol and a security protocol corresponding to the server 300. According to an embodiment of the present invention, the server interworking unit 240 may be configured to send the cryptographic data (c) to the server 300 at a specified time point before or after the cryptographic data c is transmitted to the server 300 by the identification value registration unit 230 The server 300 can confirm the terminal identification value registered in the server 300 and transmit the confirmed terminal identification value to the server 300. [

The server interworking unit 240 receives cipher data (s) obtained by encrypting data (s) including a server-side random number code dynamically generated by the server 300 from the server 300, And provides cipher data (s) to the chip interlocking unit 235.

The chip interlocking unit 235 provides the cipher data (s) to the chip 105 of the interfaced USIM 100. The chip 105 of the USIM 100 provides an authentication code corresponding to the server side random number code included in the data s decrypted through the specified decryption module 120 with the encrypted data s.

The chip interlocking unit 235 receives the authentication code from the chip 105 of the interfaced USIM 100 and the code checking unit 245 receives from the chip 105 of the interfaced USIM 100 Confirm the authentication code. The code output unit 250 outputs the verified authentication code through the screen output unit 202. According to the embodiment of the present invention, the code transmitting unit 255 can transmit the verified authentication code to the designated authentication server.

FIG. 3 is a diagram illustrating a configuration of a server 300 according to an embodiment of the present invention.

3 is a block diagram showing a configuration of receiving encrypted data c generated by the chip 105 of the USIM 100 shown in FIG. 1 through the wireless terminal 200 shown in FIG. 2, (S) encrypted with the decryption module 120 of the chip 105 so as to decrypt the data (s) including the server-side random number code dynamically generated according to the rule to the wireless terminal 200 So that the wireless terminal 200 provides the encrypted data s to the chip 105 of the USIM 100 and then receives and outputs the authentication code from the chip 105 of the USIM 100 3 is a block diagram illustrating the configuration of the server 300. It is to be understood by those skilled in the art that reference to and / or modification of the FIG. 3 may be applied to various implementations of the configuration of the server 300 , Some of the components are omitted, or the subdivided or merged thread Would be able to infer the method), the present invention is made, including any exemplary way in which the inference, to which the technical feature that is not limited to the exemplary method shown in the figure 3.

The server 300 of the present invention processes the chip 105 and the end-to-end authentication of the USIM 100 shown in FIG. 1, and transmits data including the server-side random number code dynamically generated according to the designated code generation rule s) encrypted by the decryption module 120 of the chip 105 so as to be decryptable is transmitted to the wireless terminal 200. In this case, The configuration of the server 300 shown in FIG. 3 may be implemented through a physical server provided on a network, or a program module implemented on a server (e.g., a banking server, a payment approval server, etc.) . &Lt; / RTI &gt; That is, it is evident that the present invention is not limited by the manner in which the server 300 of the present invention is implemented.

3, the server 300 includes a member management unit 305 for registering and authenticating a user as a member, a program for authenticating the validity of the program 215 loaded on the mobile terminal 200 of FIG. 2, An authentication unit 310 and an information storage unit 315 for registering and storing information for end-to-end authentication with the chip 105 of the USIM 100 of FIG. 1 through the wireless terminal 200 of FIG. 2 Respectively.

The member operation unit 305 receives a user as a member. The subscription may be performed in cooperation with the subscription / authentication unit 220 of the program 215 shown in FIG. 2, or may be performed through a separate user terminal in addition to the mobile terminal 200 of FIG. Or a management terminal 365 provided at the personalization agent at the time of issuing the USIM 100 of FIG. 1 to the user or a management terminal 365 managing the server 300. [

When the user wishes to receive an authentication code based on end-to-end authentication between the chip 105 of the USIM 100 and the server 300 using the wireless terminal 200, It is possible to process member authentication for the user in conjunction with the membership subscription / authentication unit 220 of the program 215 provided in the wireless terminal 200. [

Meanwhile, an end-to-end authentication based server authentication code service between the chip 105 and the server 300 of the USIM 100 according to the present invention may be provided only through program authentication or terminal authentication without membership registration, (E.g., a banking server, a payment approval server, etc.), the member operation unit 305 may be omitted.

The program authentication unit 310 may be configured to control the program 215 included in the wireless terminal 200 according to the first to sixth program authentication methods in cooperation with the authentication procedure unit 225 of the program 215 shown in FIG. And the like.

The information storage unit 315 stores the information allocated to the program 215 and the program stored in the program 215 in the process of authenticating the validity of the program 215 provided in the wireless terminal 200 through the program authentication unit 310. [ The terminal identification value including at least one of the information stored in the wireless terminal 200 by the terminal 215 and / or the identification value registration unit 230 of the program 215 shown in FIG. 2, Information stored in the read area of the terminal 200, information stored in the unique storage area of the wireless terminal 200, information recorded in the H / W configuration of the wireless terminal 200, Identifies a terminal identification value including at least one of information assigned / assigned in the network, and stores the identified terminal identification value in a designated storage medium.

The information storage unit 315 is transmitted from the chip 105 of the USIM 100 in cooperation with a management terminal 365 provided in the personalization agent or a management terminal 365 managing the server 300 The information to be included in the encrypted data (c) is registered and stored in a designated storage medium. Preferably, the information storage unit 315 stores a unique code (e.g., a card serial number or a chip serial number (CSN) stored in a designated unique area of the chip 105, an application area (e.g., A code value stored in an area in which the applet is recorded, and the like) can be registered and stored in a designated storage medium.

If the server-side random number code is generated through a specified code generation rule, the information storage unit 315 may identify at least one seed value to be applied to the code generation rule and store the seed value in a designated storage medium.

Referring to FIG. 3, the server 300 transmits data (c) including a time value provided by the wireless terminal 200 to the chip 105 of the USIM 100, A decryption processing unit (325) for decrypting the received encrypted data (c) through a designated decryption method, a decryption processing unit (325) for decrypting the decrypted data and a time registration unit 335 for storing the confirmed time value. The validity checking unit 330 determines whether the validity of the USIM 100 or the wireless terminal 200 is valid, And an authentication processing unit 340 for authenticating the user.

When the program 215 of the wireless terminal 200 shown in FIG. 2 acquires the time value and provides it to the chip 105 of the USIM 100 shown in FIG. 1, the chip 105 of the USIM 100 C) decrypting the data (c) including the time value in a decryptable manner in the server 300 through the designated cryptographic module 115 to generate cryptographic data (c), and generating the generated cryptographic data (c) To the wireless terminal 200. The wireless terminal 200 transmits the encryption data c provided from the chip 105 of the USIM 100 to the server 300. [

The data receiving unit 320 receives the cipher data c generated through the chip 105 of the USIM 100 from the wireless terminal 200. According to the embodiment of the present invention, the wireless terminal 200 can transmit the terminal identification value to the wireless terminal 200 at a designated time point before, during, or after the cipher data c is burned, The receiving unit 320 receives the terminal identification value, and the authentication processing unit 340 can authenticate the validity of the received terminal identification value through the terminal identification value stored in the designated storage medium.

The decryption processing unit 325 decrypts the received encrypted data c according to the designated decryption method and the information verification unit 330 decrypts the decrypted data c The time registration unit 335 identifies the time value included in the decrypted data c from the chip 105 and the server 105 of the USIM 100 according to the present invention. (For example, a reference value for authenticating whether a specified procedure is being performed according to a specified time sequence and detecting whether or not a hacking through third party intervention is performed) specified between the end-to-end authentication based server authentication code service And stores it on a storage medium.

According to the first server-side extended decoding method of the present invention, the data (c) may further include a unique code assigned in the chip 105 of the USIM 100, (C), and the authentication processing unit (340) authenticates the validity of the unique code identified from the decrypted data (c) through the unique code stored in the designated storage medium, so that the USIM 100) can be authenticated as a valid USIM 100 issued to the user through the personalization agent. The time registering unit 335 may confirm the authenticated time of the USIM 100 and may store the confirmed time in the storage medium designated as one of the time stamps. Also, even if the USIM 100 is not authenticated, the time registering unit 335 may store the unauthorized time of the USIM 100 in a storage medium designated as one of the time stamps.

According to the second server-side extended decoding method of the present invention, the data (c) may further include a chip-side random number specified in the chip 105 of the USIM 100 or a real time designation, The confirmation unit 330 can confirm the chip-side random number value from the decrypted data (c).

According to the third server side extended decoding method of the present invention, the data (c) may further include a key value (1) designated in the chip 105 of the USIM 100, (1) from the decrypted data (c).

Referring to FIG. 3, the server 300 includes a code generator 345 for confirming a dynamically generated server-side random number code according to a designated code generation rule, An encryption processing unit 350 for encrypting the encrypted data s by decryption through the decryption module 120 of the chip 105 to generate encrypted data s; And a data transmission unit 355 for transmitting the encrypted data s to the wireless terminal 200. The authentication code provided to the wireless terminal 200 from the chip 105 of the USIM 100, And a code authentication control unit (360) for controlling the authentication process to be performed.

The code generation unit 345 dynamically generates a server-side random number code using the designated code generation rule or a server-side random number code dynamically generated through the designated code generation server 370.

According to the first random number generation method of the present invention, the code generation unit 345 or the code generation server 370 generates a random number value of the designated byte in the designated random number algorithm (code generation rule) You can decide.

According to the second random number generating method of the present invention, the code generating unit 345 or the code generating server 370 may generate the random number code from the decoded data (c) A server side random number code can be dynamically generated by using a seed of a hash algorithm for code generation and a rule (optional) using at least one seed provided on the server side.

According to the third random number code generation method of the present invention, the code generation unit 345 or the code generation server 370 uses the chip side random number value identified from the decoded data (c) as a seed of the designated code generation rule To generate server-side random number codes dynamically.

According to the fourth random number generating method of the present invention, the code generating unit 345 or the code generating server 370 may generate the key value (1) identified from the decrypted data (c) The server side random number code can be dynamically generated.

According to the fifth random number code generation method of the present invention, the code generation unit 345 or the code generation server 370 acquires the server-side time value through the timer on the server side, You can dynamically generate server-side random number codes using a seed of the specified code generation rules.

According to the sixth random number code generation method of the present invention, the code generation unit 345 or the code generation server 370 determines seeds by combining at least one of the first to fifth random number code generation methods, Then, the determined seed is applied to the designated code generation rule to dynamically generate the server-side random number code. For example, the code generation unit 345 or the code generation server 370 can dynamically generate a server-side random number code using the random number value generated through the first random number code generation method as a seed of the designated code generation rule have. Alternatively, the code generation unit 345 or the code generation server 370 may use the random value generated through the first random number code generation method and the time value confirmed through the second random number code generation method as a seed of the designated code generation rule To generate server-side random number codes dynamically. Alternatively, the code generation unit 345 or the code generation server 370 may generate the chip-side random number value confirmed through the third random number code generation method and the key value (1) You can dynamically generate server-side random number codes using a seed of rules. The server-side random number code of the present invention can be selected by a person skilled in the art to include information determined through any of the first to fifth random number code generation schemes as a seed of the code generation rule, It will be clear that the present invention encompasses all implementations that can be derived through code generation schemes.

According to the embodiment of the present invention, the time registering unit 335 can confirm the time at which the server side random number code is generated, and store the confirmed time in the storage medium designated as one of the time stamps.

When the server side random number code is confirmed through the code generation unit 345, the encryption processing unit 350 composes the data (s) including the server side random number code, and the chip 105 of the USIM 100, (S) so as to be decryptable through the decryption module 120 provided in the encryption module (c).

According to the server-side extended cryptosystem of the present invention, the data (s) further includes a MAC generated using the information identified from the decrypted data (c), or the generated MAC and the key value 1 ). &Lt; / RTI &gt;

If the data s includes a MAC, the encryption processing unit 350 transmits the chip side random number and the key value 1 identified from the decrypted data c to a designated encryption method (e.g., the USIM 100 ) With a cryptographic algorithm of the cryptographic module 115 provided in the chip 105 of the mobile terminal 100) to generate the key value 2. Preferably, the key value (2) is a temporary key for generating a MAC. When the key value (2) is generated, the encryption processing unit (350) encrypts the server side random number code confirmed through the code generation unit (345) and the generated key value (2) (3). Preferably, the key value (3) is a session key. When the key value (3) is generated, the encryption processing unit (350) generates the MAC by encrypting the chip side random number value and the key value (3) using a designated encryption method. According to an embodiment of the present invention, the time registering unit 335 can confirm the time at which the MAC was generated, and store the confirmed time in the storage medium designated as one of the time stamps. Meanwhile, the MAC generation method of the present invention is not limited to the above description, and it is clear that the MAC generation method can be modified by those skilled in the art, and that the present invention includes all of the modified methods.

The data transmitting unit 355 transmits the generated encrypted data s to the wireless terminal 200 and the time registering unit 335 transmits the encrypted data s to the wireless terminal 200 Confirms the time, and stores the confirmed time in the storage medium designated as one of the time stamps.

The wireless terminal 200 provides the encrypted data s to the chip 105 of the USIM 100 and the chip 105 of the USIM 100 decrypts the encrypted data s, Determines the authentication code corresponding to the server side random number code included in the decrypted data s and provides the authentication code to the wireless terminal 200. The wireless terminal 200 transmits the authentication code corresponding to the server side random number code included in the decrypted data 105, &lt; / RTI &gt;

The code authentication control unit 360 stores (or maintains) the server side random number code included in the data s so that the authentication code output through the wireless terminal 200 is transmitted to the designated transaction terminal or the wireless terminal 200 The server 300 or the designated authentication server, the validity of the received authentication code is authenticated based on the stored (or maintained) server-side random number code. If the server side random number code and the authentication code are different in type, the code authentication control unit 360 stores (or maintains) rules for transforming or processing the server side random number code into the form of the authentication code, Alternatively, the server side random number code may be modified or processed in the form of the authentication code according to the rule, and stored (or maintained) so that the validity of the authentication code is authenticated. When the validity of the authentication code is authenticated under the control of the code authentication control unit 360, the time registering unit 335 confirms the time at which the authentication code is authenticated, and sets the confirmed time as one of the time stamps And stores it in a designated storage medium.

Hereinafter, the chip 105 of the USIM 100 shown in FIG. 1 and the server 300 of FIG. 3 perform end-to-end authentication via the wireless terminal 200 shown in FIG. 2, A method for outputting the authentication code provided by the chip 105 of the USIM 100 through the wireless terminal 200 will be described. However, the following method will be described in the form of a preferable combination for each of the methods shown in Figs. 1, 2, and 3 for convenience.

FIG. 4 illustrates an end-to-end authentication process in which the server 300 authenticates the USIM 100 according to an embodiment of the present invention.

4 shows an example in which the server 300 generates cipher data c from the chip 105 of the USIM 100 and transmits the cipher data c to the server 300 through the wireless terminal 200, The validity of the USIM 100 may be verified through the authentication process of FIG. 1. Referring to FIG. 4 and / or modified by a person skilled in the art to which the present invention pertains, It is to be understood that the present invention is not limited to the embodiment (s), but it is to be understood that the invention may be practiced otherwise than as specifically described herein, Technical features are not limited.

The wireless terminal 200 may perform at least one of the following procedures: (1) download and install the program 215, (2) register / authenticate a user, (3) (Step 400). If the chip 105 of the USIM 100 is interfaced, the wireless terminal 200 acquires 405 the time value to be provided to the chip 105 of the USIM 100, (410) with a time value. PIN authentication may be performed in the process of providing the time value according to the method.

The chip 105 of the USIM 100 receives the time value 415 and checks the unique code, the chip side random number value and the key value 1 to be included in the data c 420, (C) including the time value, the chip side random number value, and the key value (1) through the cipher module 115 designated so as to be decryptable in the designated server 300 425).

If the cipher data c is generated, the chip 105 of the USIM 100 provides the cipher data c to the wireless terminal 200, and the wireless terminal 200 transmits the cipher data c The data c is received (435).

The wireless terminal 200 confirms the terminal identification value for terminal authentication in operation 440 and transmits the cryptographic data c and the terminal identification value to the designated server 300 in operation 445. The server 300 receives the cipher data c and the terminal identification value from the wireless terminal 200 (450).

The server 300 authenticates the validity of the wireless terminal 200 that transmitted the cipher data c by authenticating the received terminal identification value using the registered terminal identification value (455). If the validity of the wireless terminal 200 is not authenticated, the server 300 provides an authentication error to the wireless terminal 200 (460), stores the time when the authentication error is provided (460) The wireless terminal 200 receives the authentication error from the server 300 and outputs the authentication error (465).

If the validity of the wireless terminal 200 is authenticated, the server 300 stores the authenticated time of the wireless terminal 200 (470) and decrypts the received encrypted data (c) 470 ). The server 300 stores the decrypted time of the ciphered data c 475 and checks the unique code, the time value, the chip-side random number, and the key value 1 from the decrypted data c (475).

The server 300 stores the confirmed time value from the decrypted data c and authenticates the validity of the unique code identified from the decrypted data c through the previously registered unique code, The validity of the USIM 100 that generated the encrypted data (c) is authenticated (485). If the validity of the USIM 100 is not authenticated, the server 300 provides an authentication error to the wireless terminal 200 (460), stores the time at which the authentication error was provided (460) The terminal 200 receives the authentication error from the server 300 and outputs the authentication error (465). Meanwhile, when the validity of the USIM 100 is authenticated, the server 300 stores the validated time of the validity of the USIM 100 (490).

FIG. 5 illustrates an end-to-end authentication process in which the USIM 100 authenticates the server 300 according to an embodiment of the present invention.

5 shows a case where the server 105 generates and transmits the cipher data s and the chip 105 of the USIM 100 receives the cipher data s through the wireless terminal 200, If the person skilled in the art realizes the validity of the end-to-end authentication process 300, referring to and / or modifying FIG. 5, For example, some of the steps may be omitted or the order may be changed. However, the present invention includes all of the above-described embodiments, and the technical features of the method of FIG. It is not limited.

When the validity of the wireless terminal 200 and the USIM 100 is authenticated through the process shown in FIG. 4, the server 300 dynamically generates the random number code through a designated code generation rule, And checks the dynamically generated random number code through the server 370 (500). Preferably, the server 300 identifies a server-side random number code generated by the first to sixth random number code generation methods of FIG.

When the server side random number code is confirmed, the server 300 stores the time at which the server side random number code was generated (505), and determines the chip side random number value and the key value 1 (1) from the decoded data (510), encrypts the server-side random number code and the generated key value (2) with a designated encryption method to generate a key value (3) 515, and generates the MAC by encrypting the chip-side random number and the key value (3) using a designated cipher method (520), and stores the generated time (520).

The server 300 transmits data (s) including the generated MAC, the confirmed server side random number code and the key value (1) to a decoding module 120 provided in the chip 105 of the USIM 100 ) To generate decrypted data s (525).

If the cipher data s is generated, the server 300 provides the cipher data s to the wireless terminal 200 in step 530 and determines the time when the cipher data s is generated / transmitted (530).

The wireless terminal 200 receives the encrypted data s from the server 300 and provides the encrypted data s to the chip 105 of the interfaced USIM 100 in operation 540. [ . PIN authentication can be performed in the process of providing the encrypted data (s) according to the method.

The chip 105 of the USIM 100 receives the encrypted data s 54 and decrypts the encrypted data s through a designated decryption module 120 to generate decrypted data s s), the server side random number code, and the key value (1) (step 555).

The chip 105 of the USIM 100 checks 555 the validity of the identified key value 1 from the decrypted data s via the key value 1 included in the data s, The validity of the server 300 that generated the server-side random number code or the validity of the server-side random number code generated by the server 300 is authenticated. If the validity of the key value (1) is not authenticated, the chip 105 of the USIM 100 provides an authentication error to the wireless terminal 200 (560) And receives and outputs the authentication error (565).

If the validity of the key value 1 is authenticated, the chip 105 of the USIM 100 encrypts the chip-side random number value and the key value 1 through the designated cryptographic module 115, (560), encrypts the server-side random number code and the generated key value (2) through the cryptographic module 115 to generate a key value (3) (565), and the cryptographic module (115) (570) by encrypting the chip-side random number and the key value (3) through the generated MAC (575), and verifying the validity of the MAC confirmed from the decrypted data (s) , The validity of the server 300 that generated the server-side random number code or the validity of the server-side random number code generated by the server 300 is authenticated. If validity of the MAC is not authenticated, the chip 105 of the USIM 100 provides an authentication error to the wireless terminal 200 (560), and the wireless terminal 200 receives the authentication error And outputs it (565).

FIG. 6 illustrates a process of providing an authentication code according to an embodiment of the present invention.

6, after processing the end-to-end authentication between the chip 105 of the USIM 100 and the server 300 through the process shown in FIGS. 4 to 5, the chip of the USIM 100 Side random number code, the wireless terminal 200 receives the authentication code and outputs the authentication code. The wireless terminal 200 is a person skilled in the art to which the present invention pertains It is possible to refer to and / or modify the FIG. 6 to various implementations of the authentication code providing process (for example, omitting some steps or changing the order). However, And the technical features of the present invention are not limited by the method shown in FIG.

When the server 300 authenticates the USIM 100 through the process shown in FIG. 4 and the USIM 100 authenticates the server 300 through the process shown in FIG. 5, The chip 105 is generated by the server 300 as a result of end-to-end authentication between the server 105 and the chip 105 of the USIM 100 processed through the processes shown in FIGS. And determines an authentication code corresponding to the server-side random number code (600). The authentication code corresponding to the server-side random number code may include at least one code among the server-side random number code, a part of the server-side random number code, and a code generated by processing the server-side random number code.

If the authentication code corresponding to the server side random number code is determined, the chip 105 of the USIM 100 provides the authentication code to the wireless terminal 200 (605), and the wireless terminal 200 The authentication code is received (610) and the received authentication code is output (615).

100: USIM 105: Chip
110: control unit 115: cryptographic module
120: decoding module 125: information receiving unit
130: encryption processing unit 135: data transmission unit
140: Data receiving unit 145: Authentication processing unit
150: decoding processing unit 155:
160: interface unit 165: memory unit
170: contact point 200: wireless terminal
215: Program 300: Server

Claims (20)

A method of providing a server-type authentication code using an end-to-end authentication between a USIM and a server, the USIM being implemented in a chip of a Universal Subscriber Identity Module (USIM)
A first step of receiving a time value from an interfaced wireless terminal;
A second step of generating encrypted data (c) obtained by encrypting data (c) including the time value;
(C) providing encrypted data (c) to the interfaced wireless terminal; (c) transmitting encrypted data (c) to the server through the wireless terminal;
A fourth step of receiving encrypted data (s) obtained by encrypting data (s) including a server-side random number code dynamically generated by the server through the interfaced wireless terminal;
A fifth step of confirming a server side random number code from data (s) obtained by decoding the encrypted data (s); And
And providing an authentication code corresponding to the server-side random number code to the interfaced wireless terminal. The server-type authentication code providing method using the end-to-end authentication between the USIM and the server.
2. The method according to claim 1, wherein the data (c)
Wherein the server is further configured to transmit the server-type authentication code using the end-to-end authentication between the USIM and the server.
2. The method according to claim 1, wherein the data (c)
And the server side authentication code further includes a chip side random number value.
2. The method according to claim 1, wherein the data (c)
And a key value (1) assigned to the server. The server-type authentication code providing method using the end-to-end authentication between the USIM and the server.
2. The method according to claim 1, wherein the encrypted data (c)
Wherein the server-type authentication code is transmitted to a designated server through the wireless terminal and is decrypted.
The method according to claim 1,
Further comprising the step of processing a designated authentication procedure to provide the authentication code to the interfaced wireless terminal. &Lt; Desc / Clms Page number 13 &gt;
The method according to claim 1,
The data (s) further includes a MAC (Message Authentication Code) generated through the server,
A step 5-1) of encrypting the chip-side random number and the key value (1) with a designated encryption method to generate a key value (2);
A fifth step of encrypting the random number code and the key value (2) with a designated encryption method to generate a key value (3);
A fifth step of encrypting the chip-side random number and the key value (3) using a predetermined encryption method to generate a MAC; And
And authenticating the MAC identified from the decrypted data (s) using the generated MAC. The server-type authentication code using the end-to-end authentication between the USIM and the server Way.
8. The method according to claim 7,
When the MAC identified from the decrypted data (s) is authenticated, the authentication code corresponding to the identified random number code is provided to the wireless terminal. The server-type authentication using the end-to-end authentication between the USIM and the server Code delivery method.
The authentication system according to claim 1,
The server side random number code,
A partial code of the server side random number code,
And a code generated by processing the server-side random number code. The server-type authentication code providing method using the end-to-end authentication between the USIM and the server.
A method for providing a server-type authentication code using an end-to-end authentication between a USIM and a server, which is executed through a server communicating with a wireless terminal interfaced with a chip of a Universal Subscriber Identity Module (USIM)
A first step of receiving encrypted data (c) obtained by encrypting data (c) including a time value provided by the wireless terminal to a chip of the USIM through a cryptographic module of the chip;
A second step of decrypting the received encrypted data (c) through a designated decryption method to check a time value;
A third step of storing the confirmed time value and confirming a dynamically generated server-side random number code according to a designated code generation rule;
A fourth step of decrypting data (s) including the server-side random number code so as to be decryptable through a decryption module provided in the chip of the USIM to generate encrypted data (s); And
And transmitting the generated encrypted data (s) to the wireless terminal,
The encrypted data (s) is provided from the wireless terminal to the chip of the USIM, decrypted through the decryption module of the chip,
And an authentication code corresponding to the server-side random number code is provided to the wireless terminal. The server-type authentication code providing method using the end-to-end authentication between the USIM and the server.
11. The method of claim 10, wherein the data (c)
Wherein the server is further configured to transmit the server-type authentication code using the end-to-end authentication between the USIM and the server.
11. The method of claim 10, wherein the data (c)
And the server side authentication code further includes a chip side random number value.
11. The method of claim 10, wherein the data (c)
And a key value (1) assigned to the server. The server-type authentication code providing method using the end-to-end authentication between the USIM and the server.
11. The method according to claim 10,
And verifying the unique code from the decrypted data (c). The server-type authentication code providing method according to claim 1, further comprising:
11. The method of claim 10,
Storing a unique code assigned to a chip of the USIM in a storage medium,
The second step comprises:
Identifying a unique code from the decoded data (c); And
And authenticating the USIM by comparing the authenticated unique code with the stored unique code. The method of claim 1, further comprising:
11. The method according to claim 10,
And verifying a chip-side random number value from the decrypted data (c). The method of claim 1,
11. The method according to claim 10,
Further comprising the step of verifying the key value (1) from the decrypted data (c).
11. The method according to claim 10,
Wherein the random number code is dynamically generated through a designated code generation rule or a random number code generated dynamically through a designated code generation server is verified through the use of an end-to-end authentication between the USIM and the server.
11. The method of claim 10,
A third step of encrypting the chip-side random number and the key value (1) identified from the decrypted data (c) by a designated encryption method to generate a key value (2);
A third step (3-2) of encrypting the server-side random number code and the key value (2) with a designated encryption method to generate a key value (3); And
And a third step (3) of encrypting the chip-side random number and the key value (3) with a designated cipher method to generate a MAC (Message Authentication Code)
Wherein the fourth step encrypts the MAC, the random number code, and the key value (1), and the server-type authentication code providing method using the end-to-end authentication between the USIM and the server
The method as claimed in claim 19,
And a cipher system for matching the cipher system of the cipher module with the cipher system of the cipher module of the chip.

Images