KR20120021117A - Card - Google Patents

Abstract

PURPOSE: A card is provided to offer a safe card transaction to a user by recognizing a code image on the card through the camera of a terminal apparatus. CONSTITUTION: An input module(140) receives a code image output request signal from a user. A creation module(160) dynamically creates the other constitution value by extracting a part of the card information constitution value from a storage module or an IC(Integrated Circuit) chip. The creation module constitutes one-time card information by combining the part of the card information constitution value with the dynamical creation value. The creation module creates an encoded bit string including the one-time card information. An encoding module(165) creates code image data by encoding the encoded bit string.

Description

Card {Card}

According to the present invention, a coded bit string in which single-use card information including one or more dynamically generated values dynamically generated among the configuration values of user card information is inserted is arranged in light or dark cells that are adjacent to each other or intersect according to a predetermined matrix alignment structure. It relates to a card that is converted to an image and output electronically.

The method of providing a card transaction (eg, payment settlement, financial transaction, etc.) using an IC card having an IC (Integrated Circuit) chip or an MS card having a magnetic stripe (MS) is a card in a face-to-face state. A face-to-face transaction method that reads card information recorded on the IC chip (or magnetic stripe) through a reader to provide a card transaction, and the user embosses the card after performing face-to-face authentication with the user in a face-to-face state. The card information can be divided into non-face-to-face transactions that provide non-face-to-face card transactions. However, the face-to-face transaction method has a problem that a card reader must be provided, and the face-to-face transaction method does not have to be provided with a card reader, but requires a complex face-to-face authentication process to authenticate a user in a face-to-face state. It is uncomfortable.

Recently, smart phones are equipped with more powerful processors and various additional devices than mobile phones and can freely install and operate applications. Thanks to the activation of the smart phone, there is a need to use the smart phone as a means of card transactions to provide payment (or financial transactions) (Needs). If the smartphone is used as a means of card transaction, since the smartphone does not have a card reader, the card transaction method provided through the smartphone will adopt a non-face-to-face transaction method of a key input method.

However, while smartphones are free to mount and operate applications, they are not as secure and jailbreak as conventional mobile phones, and unlike other personal computers, there is a risk that they can be lost at any time. Card transactions will be more complicated than conventional key input methods.

In Korea, on the other hand, in order to provide non-face-to-face transactions, KFTC's 2-Factor security recommendation must be satisfied. This is not an exception for smart card transactions. Two-factor security recommendations require that the physical media providing non-face-to-face transactions be separated from the physical media providing security for non-face-to-face transactions. Transactions that do not meet the two-factor security recommendations should be dealt with as the transaction method becomes more complex. The amount is also limited.

In other words, based on the technology developed so far, there is no particular problem in providing various card transactions through smartphones, but due to the physical and operational characteristics of smartphones, card transactions through smartphones are conventional non-face-to-face transactions. It can only be provided in the form of a collection of problems and inconveniences.

Summary of the Invention An object of the present invention for solving the above problems is a matrix alignment structure in which a coded bit string into which single-use card information is inserted, including one or more dynamically generated values dynamically generated among configuration values constituting user card information, is preset. According to the present invention to provide a card that is converted to the code image arranged in the light or dark cells adjacent to each other or intersected electronically output.

It is another object of the present invention to provide a card for electronically converting a coded bit string into which user card information is inserted and converting the coded bit string into a code image arranged in light or dark cells that are adjacent or intersected according to a predetermined matrix alignment structure.

The card according to the present invention comprises an upper coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion, wherein the upper insulating medium An integrated circuit (IC) chip embedded between a lower portion and a lower insulating medium portion, or a card having a magnetic strip provided outside the lower insulating medium portion, comprising: an output module for electronically outputting a code image; When the code image output request signal is input through the input module receiving the code image output request signal and the input module, the IC module or a separate storage module checks or extracts some configuration values of the card information configuration values of the user card. And dynamically generate configuration values other than the configuration values and dynamically generate the configuration values. After composing the disposable card information by combining the generated dynamic generation values, a generation module for generating an encoding bit string including the disposable card information, and encoding the encoding bit string generated by the generation module to generate code image data. A coding module for generating the generated code image data as a code image to be output to a display area of the output module, and a control module for controlling the code image generated by the coding module to be output to the code image display area of the output module. Equipped.

The card according to the present invention comprises an upper coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion, wherein the upper insulating medium A card having an IC (Integrated Circuit) chip provided between the lower portion and the lower insulating medium portion, or a card having a magnetic strip provided on the outside of the lower insulating medium portion, comprising: an output module for electronically outputting a code image; An input module receiving a code image output request signal and a code image output request signal through the input module, checking or extracting a card information configuration value of a user card from the IC chip or a separate storage module, and Encoding bits including the configured card information after all or a part of the information configuration values are constituted by the card information A coding module for generating a code image data by coding a coded bit string generated by the generating module, and generating the generated code image data as a code image to be output to a display area of the output module; And a control module for controlling a code image generated by the encoding module to be output to a code image display area of the output module.

According to the present invention, the card is composed of N (N ≧ 1) card information configuration values constituting user card information, or n (0 ≦ n <N) corresponding to some configuration values of the N card information configuration values. The apparatus may further include a storage module configured to store the fixed configuration value.

According to the present invention, the card may further include a battery for supplying power to the card, or may further include an antenna unit for applying power to the card.

According to the present invention, the storage module may be a memory provided in an IC chip, or may be provided in a separate chip embedded between the upper insulating medium portion and the lower insulating medium portion, or may be a separate memory chip.

According to the present invention, at least one of the generation module, the coding module, and the control module may be provided in the IC chip or in a separate chip embedded between the upper insulating medium part and the lower insulating medium part.

According to the present invention, the card information may include one or more of credit card information, check card information, debit card information, cash card information, account information, membership information of the user card.

According to the present invention, the control module reads a signal pattern of a code image output request signal generated through a key button of the input module so that any one of two or more heterogeneous code images is displayed in the code image display area of the output module. Can be output to

According to the present invention, the storage module stores a user pattern value for authenticating a user of the card compared with a signal pattern of a code image output request signal generated through a key button of the input module, and the control module stores the code The user pattern may be authenticated by reading a signal pattern of an image output request signal and comparing the user pattern value with a signal pattern value derived from the signal pattern.

According to the present invention, the input module includes a plurality of key buttons for generating a key input signal, and the storage module is compared with a key input signal generated through a key button of the input module to authenticate a user. The controller may authenticate the user by comparing the user authentication value with a key input value derived by reading the key input signal.

According to the present invention, the generation module may generate a volatile authentication value having a specified number of digits and insert the volatile authentication value into the encoding bit stream.

According to the present invention, the storage module may store one or more fixed authentication values for the card, and the generation module may further insert the fixed authentication value into the encoded bit string.

According to the present invention, the storage module stores a unique identification value that uniquely identifies the card, and the generation module further inserts the unique identification value into the encoding bit stream, or in a spare area of a card information reading structure. Can be inserted.

According to the present invention, the storage module may store an encryption key value, and the generation module may encrypt the encoding bit string (or a portion of the encoding bit string) through the encryption key value.

According to the present invention, the storage module stores a key generation value for generating an encryption key, and after the generation module generates an encryption key value through the key generation value, the encoding bit string (or part of the encoding bit string). May be encrypted using the generated encryption key value.

According to the present invention, the storage module may store an encryption key value, and the generation module may further insert the encryption key value into the encoding bit string.

According to the present invention, the storage module may store a key generation value for generating an encryption key, and the generation module may generate an encryption key value through the key generation value and insert the encryption key value into the encoding bit string.

According to the present invention, the storage module may store a key generation value for generating an encryption key, and the generation module may further insert the key generation value into the encoding bit string.

According to the present invention, the storage module stores the public certificate, and the generation module may encrypt the encoded bit stream (or part of the encoded bit stream) through at least one key value included in the public certificate.

According to the present invention, the storage module stores the public certificate, and the generation module includes the card information through at least one key value included in the public certificate. Can be inserted into the encoded bit string.

According to the present invention, the storage module may store the public certificate, and the generation module may further insert at least one key value included in the public certificate into the encoding bit stream.

According to the present invention, the generating module includes a dynamic seed obtaining unit obtaining at least one dynamic seed value, a fixed seed obtaining unit obtaining at least one fixed seed value, and the dynamic seed value and the fixed seed value. A value generator for generating a dynamic generation value by assigning an input value of a set random number generator (RNG), and configuring the disposable card information by combining the partial configuration value and the dynamic generation value according to a card information reading structure; It may include a card information component.

According to the present invention, the dynamic seed value is a second random number generated by using a time value obtained from a timer, a random number value generated by the random number generator (RNG), and a random number value generated by the random number generator (RNG) as a seed. When the card is provided with an antenna unit, the card may include any one of signal values generated by a terminal device proximate to the card and determined by reading a radio frequency signal received through the antenna unit.

According to the present invention, the fixed seed value is one or more storage values stored in the storage module, when the IC chip is provided in the card, one or more storage values stored in the memory of the IC chip, the antenna is provided in the card And a signal value determined by reading a radio frequency signal extracted from a terminal device adjacent to the card and received through the antenna unit.

According to the present invention, the dynamic generation value may include a seventh to fifteen digit number except for the first six digits and one digit of the sixteen digit number included in the primary account number (PAN) of the card information.

According to the present invention, the value generator is generated by substituting the dynamic seed value and the fixed seed value as an input value of a random number generator (RNG) that generates a number value of S (S≥1) digits. The number value of S) digits may be determined as the dynamic generation value.

According to the present invention, the value generator may generate a binary value of T bits by substituting the dynamic seed value and the fixed seed value as an input value of a random number generator (RNG) that generates a binary number of T (T> 1) bits. have.

According to the present invention, when a binary value of T (T> 1) bits is generated through the value generator, the generation module substitutes the generated binary value of the generated T bits into a preset encoding rule for at least one character value, It may further include a value conversion unit for converting to a symbol value and a numeric value.

A card according to the present invention is a card comprising a top coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion. An output module for electronically outputting an image, an input module for receiving a code image output request signal from a user, and when a code image output request signal is input through the input module, some configuration values of card information configuration values of a user card Identify or extract the partial configuration values from the storage module that stores the dynamic configuration, dynamically generate the remaining configuration values except for the partial configuration values, and combine the partial configuration values with the dynamically generated dynamic values to generate disposable card information. A generating module for generating an encoding bit string including the disposable card information after the configuration; An encoding module for encoding a coded bit string generated by a sex module to generate code image data, and generating the generated code image data as a code image to be output to a display area of the output module, and a code generated by the encoding module. And a control module for controlling the image to be output to the code image display area of the output module.

A card according to the present invention is a card comprising a top coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion. An output module for electronically outputting an image, an input module receiving a code image output request signal from a user, and storing a card information configuration value of a user card when a code image output request signal is input through the input module A generating module for identifying or extracting the card information configuration value from the module, configuring all or part of the card information configuration value as card information, and generating a coded bit string including the configured card information; The coded bit stream generated by the code is generated as code image data, and the generated code image A data and a control module for controlling the generated code image and the encoding module, the encoding module for generating a code image to display on the display area of the output module so that it outputs a code image display area of the output module.

According to the present invention, the card may further include an integrated circuit (IC) chip provided between the upper insulating medium portion and the lower insulating medium portion, or may further include a magnetic strip provided on an outer side of the lower insulating medium portion. . The card may further include a battery for supplying power to the card or an antenna unit for applying power to the card.

According to the present invention, the card is composed of N (N ≧ 1) card information configuration values constituting user card information, or n (0 ≦ n <N) corresponding to some configuration values of the N card information configuration values. The apparatus may further include a storage module configured to store the fixed configuration value.

According to the present invention, the card information may include one or more of credit card information, check card information, debit card information, cash card information, account information, membership information of the user card.

According to the present invention, the control module reads a signal pattern of a code image output request signal generated through a key button of the input module so that any one of two or more heterogeneous code images is displayed in the code image display area of the output module. Can be output to

According to the present invention, the control module reads a signal pattern of a code image output request signal generated through a key button of the input module so that any one of two or more heterogeneous code images is displayed in the code image display area of the output module. Can be output to

According to the present invention, the storage module stores a user pattern value for authenticating a user of the card compared with a signal pattern of a code image output request signal generated through a key button of the input module, and the control module stores the code The user pattern may be authenticated by reading a signal pattern of an image output request signal and comparing the user pattern value with a signal pattern value derived from the signal pattern.

According to the present invention, the input module includes a plurality of key buttons for generating a key input signal, and the storage module is compared with a key input signal generated through a key button of the input module to authenticate a user. The controller may authenticate the user by comparing the user authentication value with a key input value derived by reading the key input signal.

According to the present invention, the generation module may generate a volatile authentication value having a specified number of digits and insert the volatile authentication value into the encoding bit stream.

According to the present invention, the storage module may store one or more fixed authentication values for the card, and the generation module may further insert the fixed authentication value into the encoded bit string.

According to the present invention, the storage module stores a unique identification value that uniquely identifies the card, and the generation module further inserts the unique identification value into the encoding bit stream, or in a spare area of a card information reading structure. Can be inserted.

According to the present invention, the storage module may store an encryption key value, and the generation module may encrypt the encoding bit string (or a portion of the encoding bit string) through the encryption key value.

According to the present invention, the storage module stores a key generation value for generating an encryption key, and after the generation module generates an encryption key value through the key generation value, the encoding bit string (or part of the encoding bit string). May be encrypted using the generated encryption key value.

According to the present invention, the storage module may store an encryption key value, and the generation module may further insert the encryption key value into the encoding bit string.

According to the present invention, the storage module may store a key generation value for generating an encryption key, and the generation module may generate an encryption key value through the key generation value and insert the encryption key value into the encoding bit string.

According to the present invention, the storage module may store a key generation value for generating an encryption key, and the generation module may further insert the key generation value into the encoding bit string.

According to the present invention, the storage module stores the public certificate, and the generation module may encrypt the encoded bit stream (or part of the encoded bit stream) through at least one key value included in the public certificate.

According to the present invention, the storage module stores the public certificate, and the generation module includes the card information through at least one key value included in the public certificate. Can be inserted into the encoded bit string.

According to the present invention, the storage module may store the public certificate, and the generation module may further insert at least one key value included in the public certificate into the encoding bit stream.

According to the present invention, the generating module includes a dynamic seed obtaining unit obtaining at least one dynamic seed value, a fixed seed obtaining unit obtaining at least one fixed seed value, and the dynamic seed value and the fixed seed value. A value generator for generating a dynamic generation value by assigning an input value of a set random number generator (RNG), and configuring the disposable card information by combining the partial configuration value and the dynamic generation value according to a card information reading structure; It may include a card information component.

According to the present invention, the dynamic seed value is a second random number generated by using a time value obtained from a timer, a random number value generated by the random number generator (RNG), and a random number value generated by the random number generator (RNG) as a seed. When the card is provided with an antenna unit, the card may include any one of signal values generated by a terminal device proximate to the card and determined by reading a radio frequency signal received through the antenna unit.

According to the present invention, the fixed seed value is one or more stored values stored in the storage module, when the card is provided with an antenna unit, the radio frequency signal is extracted from the terminal device close to the card and received through the antenna unit It may include any one of the signal value to be determined.

According to the present invention, the dynamic generation value may include a seventh to fifteen digit number except for the first six digits and one digit of the sixteen digit number included in the primary account number (PAN) of the card information.

According to the present invention, the value generator is generated by substituting the dynamic seed value and the fixed seed value as an input value of a random number generator (RNG) that generates a number value of S (S≥1) digits. The number value of S) digits may be determined as the dynamic generation value.

According to the present invention, the value generator may generate a binary value of T bits by substituting the dynamic seed value and the fixed seed value as an input value of a random number generator (RNG) that generates a binary number of T (T> 1) bits. have.

According to the present invention, when a binary value of T (T> 1) bits is generated through the value generator, the generation module substitutes the generated binary value of the generated T bits into a preset encoding rule for at least one character value, It may further include a value conversion unit for converting to a symbol value and a numeric value.

According to the present invention, after electronically outputting a code image encoded card information on one side of the card, by processing the card transaction by recognizing the code image through a camera provided in the terminal device (smartphone), There is an advantage in providing a convenient and secure card transaction with two-factor security using a camera without having a separate card reader in the device (smartphone).

According to the present invention, after electronically outputting a code image of the one-time card information that is dynamically generated in the card and can be used only once on one side of the card, the code through the camera provided in the terminal device (smartphone) By recognizing an image and processing a card transaction, there is an advantage of providing a card transaction that is safer and more convenient to use than any hardware / software secure media.

1A, 1B and 1C are diagrams illustrating a card structure for processing a transaction by outputting a code image according to an embodiment of the present invention.
2 is a diagram illustrating a module configuration according to an embodiment of the present invention.
3 is a diagram illustrating a generation module function configuration for generating disposable card information according to an embodiment of the present invention.
4 is a diagram illustrating a process of encoding user card information according to an exemplary embodiment of the present invention.
5 is a diagram illustrating a process of encoding disposable card information according to an embodiment of the present invention.
6 is a diagram illustrating a process of electronically outputting a code image according to an exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings and description will be described in detail the operating principle of the preferred embodiment of the present invention. However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It is only.

1A, 1B, and 1C are diagrams showing a card structure for processing a transaction by outputting a code image according to an embodiment of the present invention.

In more detail, FIGS. 1A, 1B, and 1C illustrate disposable card information dynamically generated in the card 100 or card information of a user card issued to a user (or card identification associated with card information of the user card). Value is inserted into the coded image by arranging the encoded bit string into a code image by arranging x * y adjacent or intersecting bright or dark cells in a horizontal / vertical direction according to a predetermined matrix alignment structure. The card configuration for outputting electronically through the output module 135 is shown.

The card 100 is bonded to the upper coating medium part 105 of the transparent material, the upper insulating medium part 110 provided inside the upper coating medium part 105, and the upper insulating medium part 110. The lower layer insulating medium part 115 may be manufactured, and the lower layer insulating medium part 115 may be further provided on the outer side of the lower layer insulating medium part 115. The card 100 has a size of 85.6 mm / 54 mm in width and length, and a thickness of each of the components of the card 100 is compressed to be 0.7 mm or more and 1.2 mm or less.

A print layer for printing a preset pattern may be further provided on the outer side of the upper insulating medium unit 110. The upper coating medium unit 105 may include a print layer for the upper insulating medium unit 110. It performs a function to prevent damage. A print layer for printing a preset pattern may be further provided on the outer side of the lower insulating medium unit 115. In this case, the lower coating medium unit 120 may be a print layer of the lower insulating medium unit 115. It serves to prevent this from being tampered with.

When the card 100 is an IC card, the card 100 may further include an IC chip 125 embedded in a junction between the upper insulating medium part 110 and the lower insulating medium part 115. In this case, the card 100 is electrically connected to the eight contact terminals provided on the IC chip 125 to expose the chip on board (COB) portion and the card 100 exposed on the upper coating medium portion 105. ) May further include at least one antenna unit 150 for receiving the radio frequency signal transmitted by the terminal device close to the) and applying it to the IC chip 125. The antenna unit 150 may be manufactured to be embedded in a junction portion of the upper insulating medium unit 110 and the lower insulating medium unit 115, whereby the upper insulating medium unit 110 and the lower insulating medium unit ( An antenna buried layer is formed between the layers 115. If the card 100 is not an IC card, the IC chip 125, the COB unit and the antenna unit 150 may be omitted.

When the card 100 is an MS card, the card 100 may further include a magnetic strip 130 provided at an outer side of the lower insulating medium unit 115. If the lower coating medium 120 is provided on the card 100, the magnetic strip 130 may be manufactured to be exposed to the outside of the lower coating medium 120. If the card 100 is not an MS card, the magnetic strip 130 may be omitted.

According to the present invention, the user card issued to the user includes at least one credit card, debit card, debit card, cash card, electronic bank account, membership card, and electronically outputs the code image on one side of the card 100 The card 100 and the user card may be the same card or different cards.

The card 100 includes an output module 135 provided on one surface of the card 100 to electronically output a code image.

The output module 135 is a thin display that can be embedded in the upper insulating medium 110 while the upper insulating medium 110 inside the upper coating medium 105 is bent together. The output module 135 may be manufactured in the form of an electronic paper or a thin liquid crystal display (LCD) having a thickness of about 0.4 mm and provided on one surface of the card 100.

According to an embodiment of the present invention, the output module 135 has a code image display area for displaying a code image composed of x * y adjacent or intersecting bright or dark cells in a horizontal / vertical direction according to a predetermined matrix alignment structure. do. According to the intention of a person skilled in the art, the output module 135 further includes at least one numeric display area for displaying a number of digits specified near the code image display area, a character display area for displaying a character, and a symbol display area for displaying a symbol. can do.

The matrix alignment structure may include at least one matrix alignment structure of a data matrix standard of ISO / IEC 16022 standard or a QR code standard of ISO / IEC 18004 standard. However, the matrix alignment structure is not limited to the data matrix standard or the QR code standard, and various standards such as the PDF417 standard or the maxicode standard may be used, and the present invention is not limited by the matrix alignment structure.

The card 100 may include an input module provided on one surface of the card 100 to generate a code image output request signal for requesting the matrix display value to be displayed on the code image display area of the output module 135. 140).

The input module 140 induces a user operation (for example, applying pressure with a finger) through a printing pattern of a printing layer of the upper insulating medium unit 110, and a sensing sensor (for example, pressure) for detecting the user's operation. Sensor, an electronic sensitive sensor), and detects a user's manipulation through the key button to generate a code image output request signal.

According to an exemplary embodiment of the present invention, the input module 140 may include one key button, in which case the input module 140 displays the matrix on a code image display area of the output module 135. A code image output request signal in the form of a user input signal having one or more preset signal patterns requesting a value to be displayed may be generated.

According to another exemplary embodiment of the present invention, the input module 140 may include a plurality of key buttons, in which case the input module 140 may correspond to a user input signal corresponding to the code image output request signal, respectively. A key input signal corresponding to the key button may be generated.

According to an exemplary embodiment of the present invention, the card 100 may include all or part of information recorded in a memory (or a track of the magnetic strip 130) of the IC chip 125 of the user card issued to the user. A storage module 175 for storing corresponding user card information, storing N (N≥1) fixed configuration values constituting the user card information, or storing a card identification value associated with the user card information It may be provided.

Here, the user card information includes at least one of credit card information, check card information, debit card information, cash card information, account information and membership information.

If user card information is stored in the storage module 175, the user card information may be sorted according to a card information sorting structure and stored in the storage module 175. Here, the card information alignment structure is included in the APDU protocol when the card information stored in the memory of the IC chip 125 included in the user card through an IC card reader is included in the COB unit or the antenna unit 150. This refers to a data structure having a reading bit string read from the IC chip 125. Alternatively, when reading card information recorded in a track of the magnetic strip 130 provided in the user card through an MS card reader, the card information alignment structure may include a reading bit string read from the track of the magnetic strip 130. It means the data structure that it has.

Alternatively, when N fixed configuration values are stored in the storage module 175, the user card information is configured by combining the N fixed configuration values, and the N fixed configuration values are arranged according to the card information sorting structure. Can be.

Alternatively, when the card identification value is stored in the storage module 175, the card identification value may be a media address value on the communication network in which the card information is stored, or at least one unique identification value stored in the medium on the communication network in connection with the card information. It may include.

When the user card information (or N fixed configuration values) are stored in the storage module 175, the card 100 may store the user card information (or the N fixed configuration values) stored in the storage module 175. And a generation module 160 for generating a coded bit string into which the combined user card information) is inserted. Here, the coded bit string refers to a bit string to be inserted into a data region of a code image data structure that is converted into a code image to be output to the output module 135, and the number of bits of the coded bit string corresponds to the code image data structure. It is equal to the number of bits of the data area, and the user card information included in the encoded bit string is smaller than or equal to the number of bits of the data area.

When the user card information is stored in the storage module 175, when the code image output request signal is input through the input module 140, the generation module 160 may transmit the user card from the storage module 175. Information is extracted and a coded bit string into which the user card information is inserted is generated.

Alternatively, when the N fixed configuration values are stored in the storage module 175, when the code image output request signal is input through the input module 140, the generation module 160 stores the storage module 175. The N fixed configuration values are extracted from the N, and the N fixed configuration values are combined to form user card information, and then a coded bit string into which the user card information is inserted is generated. Here, the N fixed configuration values may be combined according to the card information alignment structure to constitute the user card information. However, the combination method of the N fixed configuration values is not limited to the card information arrangement structure, and various combination methods may be selected according to the intention of those skilled in the art.

According to an exemplary embodiment of the present invention, the user card information may be regarded as binary data to be included in the matrix alignment structure and included in the encoded bit string, in which case the user card information is a value recorded in the storage module 175. Keep the code system intact.

According to another exemplary embodiment of the present invention, the user card information may be coded according to a code system of the matrix alignment structure and included in the coded bit string. For example, when the matrix alignment structure is a data matrix specification, the user card information is coded according to an hexadecimal code system using numbers '0' through '9' and spaces, or the uppercase alphabets 'A' through 'Z'. ', Coded according to a 27-decimal code system using spaces and uppercase letters' A 'through' Z 'and numbers' 0 'through' 9 'and 37-based code systems using spaces, or by uppercase alphabets' Coded according to 41's code system using A 'through' Z 'and numbers'0' through '9' and spaces, endpoints, commas, minus, and '/', or 128 characters according to the ASCII code system. It may be included in the coded bit string.

On the other hand, when the card identification value is stored in the storage module 175, when the code image output request signal is input through the input module 140, the generation module 160 from the storage module 175 The card identification value may be extracted and a coded bit string into which the card identification value is inserted may be generated.

According to another exemplary embodiment of the present invention, the card 100 may be configured to some configuration values of N (N≥1) card information configuration values constituting all or part of the card information of the user card issued to the user. A storage module 175 may be provided to store corresponding n (0 ≦ n <N) fixed configuration values. Here, the storage module 175 stores one or more fixed configuration values valid when 'n≥1'. If 'n = 0', the storage module 175 may be omitted.

The N card information configuration values are all or part of values constituting information recorded in a memory (or a track of the magnetic strip 130) of the IC chip 125 provided in the user card issued to the user. , All or part of credit card information, all or part of check card information, all or part of debit card information, all or part of cash card information, all or part of account information, Include one or more configuration values of all or part of the membership information.

If the user card is a credit card, the N card information configuration values are designated digits of a PAN (Primary Account Number) recorded in the memory (or track of the magnetic strip 130) of the IC chip 125 of the user card. BIN (Bank Identification Number) value, serial number value, at least one verification number value, validity period value, service code value, CVV (Card Verification Value) (CVC (Card Validation Code) value, owner May contain one or more values. Or if the user card is an electronic bank account in which account information is stored, the N card information configuration values include one or more branch number values, account subject values, serial number values, and verification number values of designated digits of the PAN. It may include one or more code values and owner English name values.

When the n fixed configuration values corresponding to the partial configuration values of the N card information configuration values are stored in the storage module 175, the disposable card information may be dynamically changed within the n fixed configuration values and the card 100. It is generated by combining the (Nn) dynamic generation values generated by. If 'n = 0', the disposable card information is generated by combining N dynamically generated values dynamically generated in the card 100. Alternatively, if 'N = 1', the disposable card information includes one dynamic generation value dynamically generated in the card 100.

If the user card is a credit card, the dynamic generation value included in the disposable card information may be a 16-digit card number included in the PAN of the card information. Alternatively, the serial number may have a value of 9 digits from the seventh to the fifteenth digit except the first six digits and the last one digit of the sixteen digit numbers included in the PAN. However, the dynamic generation value is never limited to the card number or a part number of the card number, and the card number is also not limited to the 16 digit number. For example, even if the user card is a credit card, the card number of another credit card except for the visa (or master card) is not 16 digits. Or if the card number is an account number or a membership card number, the card number is not a 16 digit number.

According to an exemplary embodiment of the present invention, the N card information configuration values may be stored in the storage module 175 in a combined state according to a preset card information arrangement structure. If n fixed configuration values are stored in the storage module 175, the n fixed configuration values and the (Nn) dynamic generation values may be stored in a combined state according to a card information sorting structure. The (Nn) dynamically generated values may be stored in the form of blanks.

According to another exemplary embodiment of the present invention, the N card information configuration values may be stored in the storage module 175 in the form of a storage table or a file. In this case, only n fixed configuration values among the N card information configuration values may be selectively stored in the storage table or file format.

Referring to FIG. 1A, the storage module 175 may be implemented in the form of a memory of a module chip 155 embedded in a junction between an upper insulating medium unit 110 and a lower insulating medium unit 115 of the card 100. Can be. Here, the module chip 155 is an IC chip 125 or an RF chip embedded in the junction portion of the upper insulating medium portion 110 and the lower insulating medium portion 115. Alternatively, the storage module 175 may be implemented in the form of a memory chip (not shown) embedded in the junction of the upper insulating medium unit 110 and the lower insulating medium unit 115.

Referring to FIGS. 1B and 1C, when the IC chip 125 is provided at the junction between the upper insulating medium unit 110 and the lower insulating medium unit 115 of the card 100, the storage module 175 The memory may be implemented in the memory of the IC chip 125. Here, the memory of the IC chip 125 is allocated a storage area for storing the user card information (or N fixed configuration values) or for storing n fixed configuration values among the N card information configuration values. An area is allocated, and a storage area allocated to the memory of the IC chip 125 corresponds to the storage module 175.

If a file for storing the user card information exists in the memory of the IC chip 125, a file for storing the user card information on the memory of the IC chip 125 corresponds to the storage module.

When the n fixed configuration values of the N card information configuration values are stored in the storage module 175, the card 100 excludes the n fixed configuration values from the N card information configuration values (Nn ) Dynamically generating one), and generating disposable card information combining the n fixed configuration values and N configuration values including (Nn) dynamic generation values, and inserting the disposable card information. And a generation module 160 for generating an encoded bit string. Here, the generation module 160 necessarily generates one or more dynamic generation values, and the data area of the code image data structure in which the disposable card information included in the encoding bit stream is converted into a code image to be output to the output module 135. Is less than or equal to the number of bits in.

If one or more fixed configuration values of the N card information configuration values are stored in the storage module 175 (n≥1), the code image output request signal is input through the input module 140. The module 160 identifies (Nn) dynamically generated values, dynamically generates the (Nn) dynamically generated values using one or more seed values corresponding to each dynamic generated value item, and stores the (Nn) dynamically generated values. One-time card information is generated by combining the n fixed configuration values extracted from 175 and the generated (Nn) dynamic generation values. Here, the n fixed configuration values and the (Nn) dynamic generation values may be combined according to the card information alignment structure to configure the disposable card information. However, the combination method of the n fixed configuration values and the (Nn) dynamic generation values is not limited to the card information alignment structure, and various combination methods may be selected according to the intention of those skilled in the art.

Alternatively, when the fixed configuration value is not stored in the storage module 175 (n = 0), when the code image output request signal is input through the input module 140, the generation module 160 may N. Identify one dynamic generation value item, dynamically generate the N dynamic generation values by using one or more seed values corresponding to each dynamic generation value item, and combine the generated N dynamic generation values to generate disposable card information. Create If 'N == 1', the generation module 160 considers the generated dynamic generation value as the disposable card information. On the other hand, if two or more dynamic generation values are generated ('N≥2'), the generation module 160 may configure the disposable card information by combining the generated dynamic generation values according to the card information alignment structure. However, the combination scheme constituting the disposable card information is not limited to the card information arrangement structure, and various combination schemes may be selected according to the intention of those skilled in the art.

According to one embodiment of the present invention, the disposable card information may be regarded as binary data to be included in the matrix alignment structure and included in the encoded bit string. In this case, each configuration value constituting the disposable card information is coded by a code system having a value recorded in a memory of the IC chip 125 (or a track of the magnetic strip 130) or by a code system defined by a person skilled in the art. And may be included in the encoded bit string. If at least one fixed configuration value is stored in the storage module 175, the fixed configuration value combined with the disposable card information may maintain the code system of the value recorded in the storage module 175.

According to another exemplary embodiment of the present invention, the disposable card information may be coded according to a code system of the matrix alignment structure and included in the coded bit string. For example, when the matrix alignment structure is a data matrix standard, the single-use card information is coded according to a decimal code system using the numbers '0' through '9' and spaces, or the uppercase alphabets 'A' through 'Z'. ', Coded according to a 27-decimal code system using spaces and uppercase letters' A 'through' Z 'and numbers' 0 'through' 9 'and 37-based code systems using spaces, or by uppercase alphabets' Coded according to 41's code system using A 'through' Z 'and numbers'0' through '9' and spaces, endpoints, commas, minus, and '/', or 128 characters according to the ASCII code system. It may be included in the coded bit string.

The card 100 generates code image data including the coded bit string in a data region of the code image data structure, and x * y corresponding to the code image data based on a finder pattern of the matrix alignment structure. Generating a coded bit stream through the generation module 160 based on a code image output request signal of the input module 140 and an encoding module 165 for generating a code image by adjoining or crossing the cells; The coding module 165 generates a code image including the coded bit string, and controls the control module 170 to control the output of the generated code image through the code image display area of the output module 135. Equipped.

When the encoding bit string is generated through the generation module 160, the encoding module 165 may include one or more bit strings (eg, corresponding to a code image data structure corresponding to the matrix alignment structure before and after the encoding bit string). Code image data by adding a prefix bit string, a header bit string, a trailer bit string, and the like. Here, the code image data is a bit string to be converted into a code image composed of x * y adjacent or intersecting bright or dark cells in a horizontal / vertical direction according to the matrix alignment structure.

When the code image data is generated, the encoding module 165 generates a code image by adjoining or crossing x * y cells corresponding to the code image data based on a finder pattern of the matrix alignment structure. The control module 170 outputs the generated code image to the code image display area of the output module 135.

Referring to FIG. 1A, the storage module 175, the generation module 160, the encoding module 165, and the control module 170 may be connected to a junction of the upper insulating medium part 110 and the lower insulating medium part 115. It may be implemented in the form of a module chip 155 is embedded.

Referring to FIG. 1B, when the IC 100 is provided in the card 100, the storage module 175 is implemented in the memory of the IC chip 125, and the generation module 160 and the encoding module are provided. The 165 and the control module 170 may be embedded in the junction of the upper insulating medium 110 and the lower insulating medium 115 to be implemented in the form of a module chip 155 connected to the IC chip 125. The output module 135 and the input module 140 are connected to the module chip 155.

Referring to FIG. 1C, when the IC 100 is provided in the card 100, the storage module 175 is implemented in the memory of the IC chip 125, and the generation module 160 and the encoding module are provided. 165 and the control module 170 may be implemented in the form of a program module calculated by the processor of the IC chip 125, the output module 135 and the input module 140 is the IC chip 125 Connected with

The card 100 includes at least one module of the output module 135, the storage module 175, the generation module 160, the encoding module 165, and the control module 170. The battery 145 may be further provided to apply power to the furnace.

The battery 145 is embedded in the junction between the upper insulating medium 110 and the lower insulating medium 115, and overlaps with other components (eg, IC chip 125, antenna, etc.) embedded in the junction. It may be manufactured so as not to increase the thickness of the card 100 is embedded in the junction.

The card 100 receives a radio frequency signal transmitted by a terminal device proximate to the card 100, derives the driving power from the radio frequency signal, and outputs the output module 135, the storage module 175, The antenna module 150 for supplying power to at least one module of the generation module 160, the encoding module 165, and the control module 170 included in the card 100 may be further provided.

The antenna unit 150 applies the received radio frequency signal to the generation module 160 (or a separate signal conversion module (not shown)) and transmits the radio to the card 100 from the terminal device. At least one signal value included in the frequency signal may be processed to be extracted.

If the IC chip 125 is provided at the junction of the upper insulating medium unit 110 and the lower insulating medium unit 115, and the antenna connected to the IC chip 125 is provided, the antenna unit 150 is The antenna connected to the IC chip 125 may be shared.

2 illustrates a module configuration according to an embodiment of the present invention.

In more detail, FIG. 2 illustrates encoding of a disposable card information dynamically generated in the card 100 or card information of a user card issued to a user (or a card identification value associated with card information of the user card). FIG. 1 illustrates a module configuration in which a bit string is converted into a code image composed of x * y adjacent or intersecting bright or dark cells in a horizontal / vertical direction according to a predetermined matrix alignment structure to be output electronically. FIG. 2 illustrates an implementation method in which the storage module 175, the generation module 160, the encoding module 165, and the control module 170 are implemented in the form of a module chip 155 for convenience. It is by no means limited, and it is evident that the module can be implemented in at least one of the implementation methods (or combinations of the implementation methods) shown in FIGS. 1A, 1B, and 1C.

The storage module 175 stores user card information, and when a code image output request signal is input through the input module 140, the generation module 160 generates a coded bit string into which the user card information is inserted. do.

Alternatively, the storage module 175 stores N fixed configuration values constituting user card information, and when a code image output request signal is input through the input module 140, the generation module 160 stores the N values. User card information is configured by combining two fixed configuration values, and then a coded bit string into which the user card information is inserted is generated.

Alternatively, the storage module 175 stores a card identification value associated with user card information, and when a code image output request signal is input through the input module 140, the generation module 160 stores the card identification value. This inserted coded bit string is generated.

Alternatively, the storage module 175 stores n (0 ≦ n <N) fixed configuration values corresponding to some of the user card information configuration values, and outputs a code image output request signal through the input module 140. When is input, the generation module 160 dynamically generates remaining configuration values except for the partial configuration values, configures the disposable card information by combining the partial configuration values and the dynamically generated dynamic generation values, and then uses the disposable card. A coded bit string containing information is generated.

The encoding module 165 codes the encoded bit string generated by the generation module 160 to generate code image data, and generates the generated code image data as a code image to be output to a display area of the display module. The control module 170 controls the code image generated by the encoding module 165 to be output to the code image display area of the output module 135.

When a plurality of key buttons are provided in the input module 140 according to an exemplary embodiment of the present invention, the storage module 175 is compared with a key input value generated through the key button of the input module 140 to allow a user. The user authentication value may be stored, and when one or more key input signals to be compared with the user authentication value are input through the input module 140, the control module 170 reads the input key input signal. The key input value may be derived, and the user who requests to output the code image to the output module 135 may be authenticated by comparing the key input value with the user authentication value.

Alternatively, when the input module 140 is provided with one key button, the storage module 175 may compare the two or more signal pattern values generated through the key buttons of the input module 140 to authenticate the user. The user pattern value may be stored, and when a code image output request signal is generated through the input module 140, the control module 170 reads a signal pattern of the input code image output request signal to obtain a signal pattern value. The user may detect and compare the detected signal pattern value with the user pattern value to authenticate the user requesting to output the code image to the output module 135. Here, the signal pattern is a signal generation pattern including one or more times the key button is pressed to generate the code image output request signal, the number of times the key button is pressed, and an interval at which the key button is pressed two or more times.

When two or more heterogeneous code images are set to be output through the output module 135 according to an embodiment of the present invention, if the input module 140 is provided with one key button, the storage module 175 receives the input. Two or more signal pattern values that can be generated through a key button of the module 140 and two or more heterogeneous code image types are connected and stored, and the control module 170 generates a code generated through a key button of the input module 140. The signal pattern of the image output request signal is read to detect a signal pattern that matches the stored signal pattern value. If any signal pattern that matches the signal pattern value is detected, the control module 170 controls the code image connected to the detected signal pattern to be output to the code image display area of the output module 135. .

Alternatively, when two or more heterogeneous code images are set to be output through the output module 135, if a plurality of key buttons are provided in the input module 140, the storage module 175 of the input module 140 may be configured. Two or more key input values input through a key button and two or more heterogeneous code image types are connected and stored, and the control module 170 stores the stored key input values through the key button of the input module 140. Detect a value that matches the keystroke. If the key input value is detected, the control module 170 controls the code image connected to the detected key input value to be output to the code image display area of the output module 135.

According to an embodiment of the present invention, the generation module 160 generates volatile authentication values having a specified number of digits using one or more seed values, and for this purpose, the storage module generates one of the seed values to be used to generate the volatile authentication values. The above fixed seed values can be stored. Here, the volatile authentication value is an authentication value that can be used only once when the encoding bit string is configured and cannot be reused.

If the volatile authentication value is generated, the generation module 160 may further insert the generated volatile authentication value into the encoded bit string. If the output module 135 includes at least one additional display area among a numeric display area, a character display area, and a symbol display area, the control module 170 may generate the generated volatile authentication value in the additional display area. You can control the display.

According to an embodiment of the present invention, the storage module 175 stores one or more fixed authentication values for the card 100, and the generation module 160 stores the encoded bit stream in the storage module 175. One or more fixed authentication values may be inserted. Here, the fixed authentication value may include any value fixed to be inserted into the encoded bit string. For example, the fixed authentication value may include a password value of the user card. If the IC chip 125 is provided in the card 100, the fixed authentication value may be selected from values stored in the IC chip 125. Alternatively, when the modules are implemented in a chip form, the fixed authentication value may include a serial number (or manufacturing number) of the chip.

When the disposable card information is generated by the generation module 160, the storage module 175 stores a unique identification value that uniquely identifies the card 100, and the generation module 160 stores the encoding bit. The unique identification value can be further inserted into the column. Here, the unique identification value is a value determined to identify the card 100 for generating the disposable card information at the server side determining the user card information through the disposable card information, the unique identification in the storage medium of the server side A value and at least one fixed seed value necessary for generating the disposable card information are connected and stored. For example, when the modules are implemented in chip form, the unique identification value may include a serial number (or serial number) of the chip.

If the disposable card information is present in the spare area not used in the card information reading structure in the process of combining, the generation module 160 may insert the unique identification value into the spare area of the card information reading structure. have.

According to an embodiment of the present invention, the storage module 175 stores the encryption key value, and the generation module 160 encrypts the encoding bit string (or a portion of the encoding bit string) through the encryption key value. Can be. For example, the generation module 160 may selectively encrypt the disposable card information or the user card information included in the encoding bit string.

Alternatively, the storage module 175 stores a key generation value for generating the encryption key, and the generation module 160 dynamically generates an encryption key value through the key generation value, and then stores the encoding bit string ( Alternatively, a portion of the encoding bit string) may be encrypted using the generated encryption key value.

According to an embodiment of the present invention, the storage module 175 stores an encryption key value to be transmitted to the terminal device recognizing the code image, and the generation module 160 further inserts the encryption key value into the encoding bit string. You can.

Alternatively, the storage module 175 stores a key generation value for dynamically generating an encryption key value to be transmitted to the terminal device recognizing the code image, and the generation module 160 stores the encryption key value through the key generation value. May be generated and inserted into the encoded bit string.

Alternatively, the storage module 175 stores a key generation value to be used to generate an encryption key in the terminal device recognizing the code image, and the generation module 160 further inserts the key generation value into the encoding bit string. Can be.

According to an embodiment of the present invention, the storage module 175 stores the user's official certificate, and when the user authentication is completed by the control module 170, the generation module 160 is included in the public certificate. The encoded bit string (or a part of the encoded bit string) may be encrypted through at least one key value. For example, the coded bit string (or a portion of the coded bit string) may be encrypted using a secret key value of the certificate or a private key value.

Alternatively, the storage module 175 stores the user's official certificate, and when the user authentication is completed by the control module 170, the generation module 160 stores at least one key value included in the public certificate. An electronic signature for some values (eg, disposable card information or user card information) inserted into the encoded bit string may be attached to the encoded bit string. The generation module 160 may encrypt a partial value inserted into the encoding bit string through the private key value of the public certificate and insert the encrypted value into the encoding bit string as the electronic signature of the partial value.

Alternatively, the storage module 175 stores the user's official certificate, and when the user authentication is completed by the control module 170, the generation module 160 is the code image of the key value included in the certificate At least one key value to be used by the terminal device recognizing a may be further inserted into the encoding bit string. For example, the generation module 160 may include the public key included in the certificate in the encoding bit string.

3 is a diagram illustrating a functional configuration of the generation module 160 for generating disposable card information according to an embodiment of the present invention.

In more detail, FIG. 3 illustrates a functional configuration of the generation module 160 generating one-time card information using one or more seed values, or generating a volatile authentication value.

Referring to FIG. 3, the generation module 160 may include: a dynamic seed obtaining unit 305 for obtaining at least one dynamic seed value, a fixed seed obtaining unit 310 for obtaining one or more fixed seed values; And a value generator 315 for generating a dynamic generation value by substituting the dynamic seed value and the fixed seed value as input values of a predetermined random number generator (RNG), and the generated dynamic generation value. A card information construction unit 325 constituting single-use card information, and a bit string construction unit 330 for inserting the single-use card information into a coded bit string of a specified number of bits, and through the value generator 315, a T information generator 315 is provided. When a binary value of a bit is generated, a value converting unit 320 for converting the generated binary value of the T bit into one or more character values, symbol values, and numeric values may be further provided. .

The dynamic seed value is a second random number value generated by using a time value obtained from the timer 300, a random number value generated by the random number generator (RNG), and a random number value generated by the random number generator (RNG) as a seed. It can contain either value. If the card 100 is provided with the antenna unit 150, the dynamic seed value is generated in the terminal device close to the card 100 to read the radio frequency signal received through the antenna unit 150 It may include a signal value to be determined. Here, the timer 300 may be provided in a chip provided with the generation module 160 or may be implemented in a separate counter module type connected to the module chip 155.

The fixed seed value may include one or more stored values stored in the storage module 175. If the IC 100 is provided in the card 100, the fixed seed value may include one or more stored values stored in the memory of the IC chip 125. If the card 100 is provided with the antenna unit 150, the fixed seed value is extracted from the memory of the terminal device close to the card 100 to receive a radio frequency signal received through the antenna unit 150 It may include a signal value determined by reading.

When at least one dynamic seed value is obtained through the dynamic seed obtaining unit 305 and at least one fixed seed value is obtained through the fixed seed obtaining unit 310, the value generator 315 generates the dynamic seed. The dynamic generation value is generated by substituting the dynamic seed value and the fixed seed value into an input value in a random number generator (RNG) to which a random number algorithm for generating a value is applied. If there are a plurality of dynamic generation values, the value generator 315 repeatedly generates the dynamic generation values by using the dynamic seed values and the fixed seed values corresponding to the dynamic generation values, or the After generating a value equal to or greater than the sum of the lengths of the plurality of dynamic generation values, the generated values may be divided by regions to determine the plurality of dynamic generation values.

According to an embodiment of the present invention, the value generator 315 substitutes the dynamic seed value and the fixed seed value as an input value of a random number generator (RNG) that generates a number value of S (S≥1) digits. After generating the number value of the S digits, the number value of s (1 ≦ s ≦ S) digits among the number values of the S digits may be determined as the dynamic generation value.

According to another exemplary embodiment of the present invention, the value generator 315 substitutes the dynamic seed value and the fixed seed value as input values of a random number generator (RNG) generating a binary of T (T> 1) bits. After generating a binary value of T bits, a binary of t (1 ≦ t ≦ T) bits among the binaries of the T bits may be determined as the dynamic generation value.

When the binary value of the T bit is generated through the value generator 315, the value converter 320 substitutes the generated binary value of the T bit into a preset encoding rule to convert one or more character values and symbol values. And a numeric value, or a combination of one or more of the above characters, symbols, and numbers.

Meanwhile, when the generation module 160 generates the volatile authentication value, the dynamic seed obtaining unit 305 obtains at least one dynamic seed value set to generate the volatile authentication value, and the fixed seed obtaining unit ( 310 obtains one or more dynamic seed values set to generate the volatile authentication value, and the value generator 315 is configured to generate a dynamic seed value to a random number generator (RNG) to which a random number algorithm for generating the volatile authentication value is applied. The volatile authentication value may be generated by substituting a fixed seed value as an input value.

According to another exemplary embodiment of the present invention, the value generator 315 dynamically generates a value having a length greater than the dynamic generated value using the dynamic seed value and the fixed seed value, and then, a part of the generated value is The dynamic generation value may be determined, and the remaining part may be determined as the volatile authentication value.

When the dynamic generation value is generated, the card information construction unit 325 configures disposable card information including the dynamic generation value. If one or more fixed configuration values are stored in the storage module 175, the card information configuration unit 325 configures the disposable card information by combining the sound fixed configuration value and the dynamic generation value.

The bit string generator inserts the disposable card information into a designated position of the encoded bit string. If the volatile authentication value is generated through the generation module 160, the bit string generator inserts the volatile authentication value into a designated position of the encoding bit string.

4 is a diagram illustrating a process of encoding user card information according to an exemplary embodiment of the present invention.

In more detail, FIG. 4 illustrates a process of generating a coded bit string into which user card information stored in the storage module 175 is inserted. If a person having ordinary knowledge in the technical field to which the present invention pertains, FIG. Although various implementation methods (e.g., some steps may be omitted or changed) may be inferred for encoding the user card information by referring to and / or modifying 4, the present invention may infer all implementation methods inferred from the above. It is made, including, and the technical features are not limited only to the implementation method shown in FIG.

Referring to FIG. 4, the control module 170 checks the code image output request signal through the input module 140 (400). If the code image output request signal is confirmed (405), the control module 170 reads a signal pattern of the code image output request signal, or a key input value input through the input module 140 to provide a user. Authenticate (410).

If the user is authenticated (415), the generation module 160 obtains N card information configuration values from the storage module 175 (e.g., memory of the IC chip 125 or a separate storage module 175). The combined user card information is obtained (420), and the user card information is inserted (425) into the encoding bit stream.

If the volatile authentication value is further inserted into the encoded bit string (430), the generation module 160 obtains the dynamic seed value and the fixed seed value to generate the volatile authentication value (435), and obtains the obtained dynamic seed value. In operation 440, a volatile authentication value is generated through the fixed seed value and inserted into the designated bit stream.

If the encoding bit string further includes a fixed value of at least one of a fixed authentication value, a unique identification value, an encryption key value, a key generation value, and at least one key value included in the public certificate (445), the generation module 160 Obtains one or more fixed values to be inserted into the encoded bit stream from the storage module 175 (450), and inserts the obtained fixed values into a designated position of the encoded bit stream (455).

Meanwhile, the encoding bit string (or a portion of the encoding bit string) may be an encryption key value (or an encryption key value generated through a key generation value) included in the storage module 175 or the storage module 175. It may be encrypted through at least one key value included in the public certificate. Alternatively, some values including the card information among the values included in the encoding bit string may be attached with an electronic signature through at least one key value included in the authentication certificate included in the storage module 175.

5 is a diagram illustrating a process of encoding disposable card information according to an exemplary embodiment of the present invention.

In more detail, FIG. 5 illustrates a process of generating a coded bit string in which single-use card information is inserted by combining n fixed configuration values and (Nn) dynamically generated values. Those skilled in the art may refer to and / or modify this drawing 5 to infer various implementation methods (e.g., some steps may be omitted or changed) for encoding the disposable card information. Although there will be, the present invention includes all the implementation methods inferred above, the technical features are not limited only to the implementation method shown in FIG.

Referring to FIG. 5, the control module 170 checks a code image output request signal through the input module 140 (500). If the code image output request signal is confirmed (505), the control module 170 reads a signal pattern of the code image output request signal, or a key input value input through the input module 140 to provide a user. Authenticate (510).

If the user is authenticated (515), the generation module 160 obtains n fixed configuration values corresponding to some of the N card information configuration values from the storage module 175 (520). If the n fixed configuration values are obtained (525), the generation module 160 generates a dynamic seed set to generate (Nn) dynamic generation values excluding the n fixed configuration values among the N card information configuration values. A value and a fixed seed value are acquired (530), and the obtained dynamic seed value and the fixed seed value are substituted into the input value of the random number generator (RNG) to generate (Nn) dynamic seed values (535).

If the (Nn) dynamic generation values are generated (540), the generation module 160 configures disposable card information by combining the n fixed configuration values and the (Nn) dynamic generation values (545), The configured single-use card information is inserted into the encoding bit stream (550). According to an embodiment of the present invention, the generation module 160 may further insert a volatile authentication value and one or more fixed values into the encoding bit stream through the process illustrated in FIG. 4.

6 is a diagram illustrating a process of electronically outputting a code image according to an exemplary embodiment of the present invention.

In more detail, FIG. 6 illustrates a process of electronically outputting a coded bit string generated through the process illustrated in FIG. 4 or FIG. 5 through a code image display area provided in the output module 135. Those skilled in the art to which the present invention pertains may perform various methods (e.g., some steps may be omitted or changed) for electronically outputting the code image by referring to and / or modifying the present invention. Method) can be inferred, but the present invention includes all the inferred implementation methods, and the technical features are not limited to the implementation method shown in FIG.

Referring to FIG. 6, when a coded bit string is generated through the process illustrated in FIG. 4 or 5, the encoding module 165 includes the coded bit string in a data area of a code image data structure to include code image data. Generate a code image outputable to the output module 135 by adjoining or intersecting x * y cells corresponding to the code image data based on a finder pattern of a matrix alignment structure (600). ).

If the code image is generated (610), the control module 170 electronically outputs the generated code image through the code image display area of the output module 135 (615).

100: card 105: upper coating medium portion
110: upper insulating medium portion 115: lower insulating medium portion
120: lower coating medium portion 125: IC chip
130: magnetic strip 135: output module
140: input module 145: battery
150: antenna unit 155: module chip
160: generation module 165: encoding module
170: control module 175: storage module

Claims (58)

An upper coating medium part of a transparent material, an upper insulating medium part provided inside the upper coating medium part, and a lower insulating medium part joined to the upper insulating medium part, and between the upper insulating medium part and the lower insulating medium part. In a card having an IC (Integrated Circuit) chip embedded in or a magnetic strip provided on the outside of the lower insulating medium portion,
An output module for electronically outputting a code image;
An input module configured to receive a code image output request signal from a user;
When a code image output request signal is input through the input module, the IC chip or a separate storage module checks or extracts some configuration values of the card information configuration values of the user card, and extracts the remaining configuration values except for the partial configuration values. A generation module configured to dynamically generate one-time card information by combining the partial configuration value and the dynamically generated dynamic generation value, and then generate a coded bit string including the one-time card information;
An encoding module for encoding a coded bit string generated by the generation module to generate code image data, and generating the generated code image data as a code image to be output to a display area of the output module; And
And a control module for controlling a code image generated by the encoding module to be output to a code image display area of the output module.
An upper coating medium part of a transparent material, an upper insulating medium part provided inside the upper coating medium part, and a lower insulating medium part joined to the upper insulating medium part, and between the upper insulating medium part and the lower insulating medium part. In the card provided with an IC (Integrated Circuit) chip, or a magnetic strip provided on the outside of the lower insulating medium portion,
An output module for electronically outputting a code image;
An input module configured to receive a code image output request signal from a user;
When a code image output request signal is input through the input module, the card information configuration value of the user card is checked or extracted from the IC chip or a separate storage module, and all or part of the card information configuration value is configured as card information. A generation module for generating an encoded bit string including the configured card information;
An encoding module for encoding a coded bit string generated by the generation module to generate code image data, and generating the generated code image data as a code image to be output to a display area of the output module; And
And a control module for controlling a code image generated by the encoding module to be output to a code image display area of the output module.
3. The method according to claim 1 or 2,
A storage module for storing fixed configuration values of n (0 ≦ n <N) corresponding to N (N ≧ 1) card information configuration values constituting user card information or some of the N card information configuration values Card further comprising a.
3. The method according to claim 1 or 2,
And a battery for supplying power to the card.
3. The method according to claim 1 or 2,
And an antenna unit for applying power to the card.
The storage module of claim 1, wherein the storage module comprises:
Is a memory provided in the IC chip, or
It is provided in a separate chip embedded between the upper insulating medium portion and the lower insulating medium portion, or
Card characterized in that the separate memory chip.
3. The method according to claim 1 or 2,
At least one of the generation module, the encoding module, and the control module is provided in the IC chip, or
And a separate chip embedded between the upper insulating medium portion and the lower insulating medium portion.
The method of claim 1 or 2, wherein the card information,
A card comprising one or more credit card information, check card information, debit card information, cash card information, account information, membership information of the user card.
The method according to claim 1 or 2, wherein the control module,
Read a signal pattern of the code image output request signal generated through the key button of the input module to control the code image of any one or more heterogeneous code images to be output to the code image display area of the output module Card.
3. The method according to claim 1 or 2,
The storage module,
Store a user pattern value for authenticating a user of the card compared with a signal pattern of a code image output request signal generated through a key button of the input module,
The control module,
And read the signal pattern of the code image output request signal, and compare the signal pattern value derived from the signal pattern with the user pattern value to authenticate the user.
3. The method according to claim 1 or 2,
The input module,
A plurality of key buttons for generating a key input signal,
The storage module,
A user authentication value for authenticating a user by comparing with a key input signal generated through a key button of the input module,
The control module,
And comparing the key input value derived by reading the key input signal with the user authentication value to authenticate the user.
The method of claim 1 or 2, wherein the generation module,
And generating a volatile authentication value having a specified number of digits and inserting the same into the encoded bit stream.
3. The method according to claim 1 or 2,
The storage module,
Store one or more fixed authentication values for the card,
The generation module,
And inserting the fixed authentication value into the encoded bit stream.
The method of claim 1,
The storage module,
Store a unique identification value that uniquely identifies the card,
The generation module,
And inserting the unique identification value into the coded bit stream or in a spare area of a card information reading structure.
3. The method according to claim 1 or 2,
The storage module,
Store the encryption key value,
The generation module,
And encrypting the encoded bit string (or a portion of the encoded bit string) through the encryption key value.
3. The method according to claim 1 or 2,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And after generating an encryption key value through the key generation value, encrypting the encoded bit string (or a portion of the encoded bit string) through the generated encryption key value.
3. The method according to claim 1 or 2,
The storage module,
Store the encryption key value,
The generation module,
And inserting the encryption key value into the encoding bit stream.
3. The method according to claim 1 or 2,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And generating an encryption key value through the key generation value and inserting the encryption key value into the encoding bit stream.
3. The method according to claim 1 or 2,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And inserting the key generation value into the encoding bit stream.
3. The method according to claim 1 or 2,
The storage module,
Save the certificate,
The generation module,
And encrypting the encoded bit string (or a portion of the encoded bit string) by using at least one key value included in the certificate.
3. The method according to claim 1 or 2,
The storage module,
Save the certificate,
The generation module,
And inserting an electronic signature for a partial value including the card information into the encoded bit string through the at least one key value included in the certificate, and inserting the digital signature into the encoded bit string.
3. The method according to claim 1 or 2,
The storage module,
Save the certificate,
The generation module,
And inserting at least one key value included in the accredited certificate into the encoding bit stream.
The method of claim 1, wherein the generation module,
A dynamic seed obtaining unit obtaining at least one dynamic seed value;
A fixed seed obtaining unit obtaining one or more fixed seed values,
A value generator for generating a dynamic generation value by substituting the dynamic seed value and the fixed seed value as input values of a predetermined random number generator;
And a card information constructing unit configured to form disposable card information by combining the partial configuration value and the dynamic generation value according to the card information reading structure.
The method of claim 23, wherein the dynamic seed value is,
The time value obtained from the timer,
Random value generated by the random number generator (RNG),
A second random value generated by using the random number value generated by the random number generator (RNG) as a seed,
When the card is provided with an antenna unit, the card comprising any one of the signal value generated by the terminal device adjacent to the card and determined by reading the radio frequency signal received through the antenna unit.
The method of claim 23, wherein the fixed seed value is,
One or more stored values stored in the storage module,
If the card is equipped with an IC chip, one or more stored values stored in a memory of the IC chip,
When the card is provided with an antenna unit, the card characterized in that it comprises any one of the signal value extracted from the terminal device adjacent to the card and determined by reading the radio frequency signal received through the antenna unit.
The method of claim 23, wherein the dynamically generated value is:
The seventh to the fifteenth digits of the sixteen digits included in the PAN (Primary Account Number) of the card information except for the first six digits, characterized in that the card comprises a.
The method of claim 23, wherein the value generating unit,
The dynamic seed value and the fixed seed value are substituted into the input value of the random number generator (RNG) generating a number value of S (S ≧ 1) digits. The card characterized in that determined by the generated value.
The method of claim 23, wherein the value generating unit,
And inserting the dynamic seed value and the fixed seed value into an input value of a random number generator (RNG) that generates a binary number of T (T> 1) bits to generate a binary value of T bits.
24. The method of claim 23,
When a binary value of the T (T> 1) bit is generated through the value generator, a value that converts the generated binary value of the T bit into one or more character values, symbol values, and numeric values by preset encoding rules. The card further comprises a conversion unit.
In a card having an upper coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion,
An output module for electronically outputting a code image;
An input module configured to receive a code image output request signal from a user;
When a code image output request signal is input through the input module, the partial configuration value is checked or extracted from a storage module that stores some configuration values of card information configuration values of a user card, and the remaining configuration values except for the partial configuration values. A generation module configured to dynamically generate the data, combine the partial configuration value with the dynamically generated dynamic generation value to configure disposable card information, and generate a coded bit string including the disposable card information;
An encoding module for encoding a coded bit string generated by the generation module to generate code image data, and generating the generated code image data as a code image to be output to a display area of the output module; And
And a control module for controlling a code image generated by the encoding module to be output to a code image display area of the output module.
In a card having an upper coating medium portion made of a transparent material, an upper insulating medium portion provided inside the upper coating medium portion, and a lower insulating medium portion bonded to the upper insulating medium portion,
An output module for electronically outputting a code image;
An input module configured to receive a code image output request signal from a user;
When a code image output request signal is input through the input module, the card information configuration value is checked or extracted from a storage module that stores the card information configuration value of the user card, and all or part of the card information configuration value is stored in the card information. A generation module configured to generate a coded bit string including the configured card information;
An encoding module for encoding a coded bit string generated by the generation module to generate code image data, and generating the generated code image data as a code image to be output to a display area of the output module; And
And a control module for controlling a code image generated by the encoding module to be output to a code image display area of the output module.
The method of claim 30 or 31,
And an integrated circuit (IC) chip provided between the upper insulating medium portion and the lower insulating medium portion.
The method of claim 30 or 31,
And a magnetic strip provided on the outer side of said lower insulating medium portion.
The method of claim 30 or 31,
A storage module for storing fixed configuration values of n (0 ≦ n <N) corresponding to N (N ≧ 1) card information configuration values constituting user card information or some of the N card information configuration values Card further comprising a.
The method of claim 30 or 31,
And a battery for supplying power to the card.
The method of claim 30 or 31,
And an antenna unit for applying power to the card.
The method of claim 30 or 31, wherein the card information,
A card comprising one or more credit card information, check card information, debit card information, cash card information, account information, membership information of the user card.
The method of claim 30 or 31, wherein the control module,
Read a signal pattern of the code image output request signal generated through the key button of the input module to control the code image of any one or more heterogeneous code images to be output to the code image display area of the output module Card.
The method of claim 30 or 31,
The storage module,
Store a user pattern value for authenticating a user of the card compared with a signal pattern of a code image output request signal generated through a key button of the input module,
The control module,
And read the signal pattern of the code image output request signal, and compare the signal pattern value derived from the signal pattern with the user pattern value to authenticate the user.
The method of claim 30 or 31,
The input module,
A plurality of key buttons for generating a key input signal,
The storage module,
A user authentication value for authenticating a user by comparing with a key input signal generated through a key button of the input module,
The control module,
And comparing the key input value derived by reading the key input signal with the user authentication value to authenticate the user.
The method of claim 30 or 31, wherein the generating module,
And generating a volatile authentication value having a specified number of digits and inserting the same into the encoded bit stream.
The method of claim 30 or 31,
The storage module,
Store one or more fixed authentication values for the card,
The generation module,
And inserting the fixed authentication value into the encoded bit stream.
The method of claim 30,
The storage module,
Store a unique identification value that uniquely identifies the card,
The generation module,
And inserting the unique identification value into the coded bit stream or in a spare area of a card information reading structure.
The method of claim 30 or 31,
The storage module,
Store the encryption key value,
The generation module,
And encrypting the encoded bit string (or a portion of the encoded bit string) through the encryption key value.
The method of claim 30 or 31,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And after generating an encryption key value through the key generation value, encrypting the encoded bit string (or a portion of the encoded bit string) through the generated encryption key value.
The method of claim 30 or 31,
The storage module,
Store the encryption key value,
The generation module,
And inserting the encryption key value into the encoding bit stream.
The method of claim 30 or 31,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And generating an encryption key value through the key generation value and inserting the encryption key value into the encoding bit stream.
The method of claim 30 or 31,
The storage module,
Store the key generation value that generates the encryption key,
The generation module,
And inserting the key generation value into the encoding bit stream.
The method of claim 30 or 31,
The storage module,
Save the certificate,
The generation module,
And encrypting the encoded bit string (or a portion of the encoded bit string) by using at least one key value included in the certificate.
The method of claim 30 or 31,
The storage module,
Save the certificate,
The generation module,
And inserting an electronic signature for a partial value including the card information into the encoded bit string through the at least one key value included in the certificate, and inserting the digital signature into the encoded bit string.
The method of claim 30 or 31,
The storage module,
Save the certificate,
The generation module,
And inserting at least one key value included in the accredited certificate into the encoding bit stream.
The method of claim 30, wherein the generation module,
A dynamic seed obtaining unit obtaining at least one dynamic seed value;
A fixed seed obtaining unit obtaining one or more fixed seed values,
A value generator for generating a dynamic generation value by substituting the dynamic seed value and the fixed seed value as input values of a predetermined random number generator;
And a card information constructing unit configured to form disposable card information by combining the partial configuration value and the dynamic generation value according to the card information reading structure.
53. The method of claim 52, wherein the dynamic seed value is
The time value obtained from the timer,
Random value generated by the random number generator (RNG),
A second random value generated by using the random number value generated by the random number generator (RNG) as a seed,
When the card is provided with an antenna unit, the card comprising any one of the signal value generated by the terminal device adjacent to the card and determined by reading the radio frequency signal received through the antenna unit.
53. The method of claim 52, wherein the fixed seed value is
One or more stored values stored in the storage module,
When the card is provided with an antenna unit, the card characterized in that it comprises any one of the signal value extracted from the terminal device adjacent to the card and determined by reading the radio frequency signal received through the antenna unit.
53. The method of claim 52, wherein the dynamically generated value is
A card comprising the seventh to fifteenth digits of the sixteen digits included in the PAN (Primary Account Number) of the card information except for the first six digits and the last one digit.
The method of claim 52, wherein the value generating unit,
The dynamic seed value and the fixed seed value are substituted into the input value of the random number generator (RNG) generating a number value of S (S ≧ 1) digits. The card characterized in that determined by the generated value.
The method of claim 52, wherein the value generating unit,
And inserting the dynamic seed value and the fixed seed value into an input value of a random number generator (RNG) that generates a binary number of T (T> 1) bits to generate a binary value of T bits.
The method of claim 52, wherein
When a binary value of the T (T> 1) bit is generated through the value generator, a value that converts the generated binary value of the T bit into one or more character values, symbol values, and numeric values by preset encoding rules. The card further comprises a conversion unit.

Images