KR101188962B1 - Optical Tag Device, Commercial Product Employing the Same, and Product Authentication Terminal for the Same - Google Patents

Abstract

According to the present invention, it is practically impossible to illegally expose and use authentication data, and a product tag device which can be authenticated multiple times, receives a product authentication signal from such a product tag device, and receives a genuine product from an external authentication server. The present invention relates to an authentication terminal capable of receiving authentication. An optical tag apparatus of the present invention, which can be attached to a product, includes a spectrum encoder for generating spectrum information according to a unique code of the product, and a light emitting unit for emitting a visible light authentication signal according to the spectrum information. In a preferred embodiment, the spectral encoder determines each color value of RGB according to the unique code, and the light emitting unit emits the visible ray authentication signal according to the determined color values.

Description

Optical Tag Device, Commercial Product Employing the Same, and Product Authentication Terminal for the Same}

The present invention relates to a product identification mark, and more particularly, to a tag device for actively outputting product information in a form recognizable by a reading device. In addition, the present invention relates to a product authentication terminal for recognizing product identification information output from such a tag device.

Not only are the trademarks or brands representing the source of the product not only the criteria for the quality of the product, but also the brand of the luxury product is a measure of the social status and dignity of the person using the product. The products of famous brands have enormous design development and marketing costs for a long time before they gain market dominance and consumer trust, but they have a large amount by those who want to take advantage of the brand's well-known reputation and take unfair advantage. Counterfeit goods often appear. Such counterfeit goods not only misunderstand the origin and quality of the goods, thereby undermining the legitimate seller's credit, but also disrupt the order of the distribution of goods, causing unpleasant buyers 'discomfort and weakening potential buyers' willingness to purchase genuine products. It is a problem.

In general, since famous products or counterfeit goods for world-class products are manufactured very similar to genuine products, it is often difficult to judge the authenticity of a consumer as well as a general consumer by design alone. Accordingly, even after purchasing a product, a user may not be sure whether the purchased product is genuine, and in some cases, even a specific institution or a manufacturer may not be able to check the authenticity. In order to solve these problems, the product serial number may be marked on the product, the logo may be displayed on the product by hologram, or the breakable seal may be attached, but no matter how elaborate and special marks can be imitated or stolen. This does not provide satisfactory results.

Therefore, there is an urgent need for a method that enables the buyer to accurately verify / confirm whether the goods purchased by him or her are genuine during and after the sale. There have been various proposals for allowing a buyer to check whether a product is genuine.

For example, Korean Patent Laid-Open Publication No. 2007-0104425 (name of the invention: a product activation system) provides a purchaser with an authentication card including an authentication number. It suggests the way for the buyer to be authenticated by accessing the authentication center and sending the authentication number. Republic of Korea Patent Publication No. 2009-0001495 (name of the invention: a method of authenticating the product using a genuine tag and wired and wireless communication) provides the buyer with a sealed activation tag, the buyer opens the tag to access the authentication server as a communication means It proposes a way to authenticate the authenticity from the authentication server by entering the numeric number of the tag. Korean Patent Laid-Open Publication No. 2006-0124675 (product name and method of identification using code, barcode and radio frequency identification) generates a scannable code based on an image or information related to the product, It suggests how to print with labels. Korean Patent Laid-Open Publication No. 2010-0070115 (name of the invention: a system for verifying authenticity and its method) proposes a method for receiving authenticity verification from an authentication server by inputting a password image and a product serial number attached to a product. Korean Patent No. 769215 (name of the invention: a method of identifying a product using a pattern code) displays a pattern code with a special pattern on a product, and then photographs the pattern code image and transmits it to the authentication server to check the authenticity. Presenting.

However, the above methods are likely to be incapacitated when a unique identifier of a product, such as an authentication number, a cryptographic image, or a pattern code, is forged identically to a genuine product.

An authentication system that attaches an RFID tag that records product information to a product, reads RFID through an RFID reader, and performs activation is also presented in various ways. Republic of Korea Patent No. 719139 (Invention: Authentication service method and system using RF ID and mobile communication terminal), Republic of Korea Patent Publication 2004-0104854 (Invention: Product identification information stored in the RFID tag can be read Mobile communication terminal and a service management method executable in a computer communicating with the terminal), Korean Patent Laid-Open Publication No. 2003-0074276 (Invention: Determination apparatus and method, management apparatus and method for a wireless ID tag and a wireless ID tag) For example, Korean Patent No. 655151 (Invention name: Apparatus and method for authenticating a genuine battery of a mobile communication terminal).

However, such an RFID system is useful for verifying product information of a mass-produced product such as a mobile communication terminal, but since RFID can be replicated in the same manner, it is not suitable for activation of expensive luxury goods. You may not. In addition, RFID systems are bulky due to components for wirelessly receiving signals and power and radiating radio waves, which makes the design more inadequate for product activation.

On the other hand, Republic of Korea Patent Publication No. 2007-0065852 (name of the invention: a method of authenticating the product using the authentication number) is coated with a gold foil, silver foil, hologram foil, etc. secret authentication number only one time authentication so as not directly visible After the display, the buyer of the product exposes the secret authentication number and confirms it, and proposes a method of authenticating from the authentication server. However, this method can be authenticated only once for each product, so that used goods buyers cannot be authenticated if the goods are sold to third parties in the used state during use.

Since activation for luxury goods requires authentication for the product itself, not for that user, data for authentication must be stored in the product itself or in a tag, and illegal exposure or use of authentication data is practically impossible. must do it. In addition, it is necessary to allow certification several times in consideration of the distribution of used goods. However, according to the existing methods, not only the authentication data can be easily copied and used, but also it is difficult to authenticate a product several times.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and it is a technical object of the present invention to provide a product tag device which is virtually impossible to be used because it is illegally exposed and used for authentication.

Another object of the present invention is to provide a method for generating product authentication information in the product tag as described above.

Another object of the present invention is to provide an authentication terminal capable of receiving product authentication information from a product tag apparatus as described above and receiving genuine product certification from an external authentication server.

The optical tag device of the present invention for achieving the above technical problem, which can be attached to a product, a spectral encoder for generating spectral information according to the unique code of the product, and light emission for emitting a visible light authentication signal according to the spectral information A part is provided.

The spectral information may be a level value for each of the color signals separated by RGB or other full color colors, or may be a level value at a specific frequency or an overall light intensity.

In a preferred embodiment, the spectral encoder determines each color value of RGB according to the unique code, and the light emitting unit emits the visible ray authentication signal according to the determined color values. The light emitting unit preferably emits a test light pattern for correcting sensitivity of the authentication terminal before the visible light authentication signal is emitted.

In a preferred embodiment, the optical tag device further comprises a storage for storing the unique code. In one embodiment, the unique code stored in the storage is a product serial number for the product. In this case, the code conversion unit generates an authentication code by a predetermined technique based on the product serial number, and the spectrum encoder determines the color values according to the authentication code. However, in other embodiments, the unique code stored in the storage may be multiple authentication codes. In this case, the spectrum encoder determines the color values according to any one selected from the plurality of authentication codes. In this case, a code selector for determining the selected code among a plurality of authentication codes may be separately provided.

The optical tag device may additionally be provided with an external switch for controlling the overall operation of the device. In addition, the optical tag device may additionally be provided with an external connection terminal for receiving a DC power from the outside.

On the other hand, in the product authentication information generation method of the present invention for achieving the above another technical problem, first generates the spectrum information according to the unique code of the product, and then emits a visible light authentication signal according to the spectrum information.

In generating the spectral information, it is preferable to determine each color value of RGB according to the unique code, and to output the visible light authentication signal according to the determined color values. In addition, it is preferable to output a test light pattern for correcting sensitivity of the authentication terminal before the visible light authentication signal is emitted.

In one embodiment, the unique code is a product serial number for the product. In this case, in generating the spectrum information, after generating an authentication code by a predetermined technique based on the product serial number, the color values are determined according to the authentication code.

In another embodiment, the plurality of authentication codes are stored in the storage device as the unique code before generating the spectrum information, and in generating the spectrum information, the color value according to any one selected from the plurality of authentication codes. Will decide.

On the other hand, the product authentication terminal of the present invention for achieving the another technical problem is to authenticate a product with a tag for emitting a visible light authentication signal that varies in spectrum according to the unique code of the product. The authentication terminal includes a display, a light receiving unit, a reception code recognition unit, and an authentication unit. The light receiving unit receives the visible light authentication signal, and the reception code recognition unit restores the unique code from the spectrum of the visible light authentication signal. The authentication unit provides the unique code to the authentication server to request authentication, receives the authentication response message, and outputs the received response message through the display.

The reception code recognition unit may determine each color value of RGB from the visible ray authentication signal, and determine the unique code according to the color value.

In a preferred embodiment, the product authentication terminal determines the test color value from the test light pattern received before the visible light authentication signal is received, and adjusts the reception sensitivity of the visible light authentication signal based on this.

In a more general aspect, the product authentication terminal of the present invention is implemented based on a program that can be executed by a data terminal. The program includes a function of receiving a visible light authentication signal emitted from a tag attached to a product, a function of restoring a unique code of the product from a spectrum of the visible light authentication signal, and providing the unique code to an authentication server for authentication. It is suitable for implementing the function of requesting a request, receiving an authentication response message, and outputting it through a display.

According to the present invention, the product producer can prevent the financial damage caused by the counterfeit goods, can secure the brand credibility, and it is easy to assure the buyer of the authenticity when selling the product.

The buyer of the product can quickly and easily check whether the product is genuine, so that the anxiety about whether the purchased product is a counterfeit product can be solved. In addition, when used to sell to others as used goods can be easily proved to be genuine, it is possible to sell used goods at full price.

As a result, the present invention can reduce market chaos or disorder caused by counterfeit goods, and contribute to establishing a sound commerce order.

In particular, according to the present invention, not only a dedicated terminal but also a terminal having a camera and having a data communication function, such as a smartphone or a PC, can be used as the authentication terminal, so that the authentication system is simple and easy to construct. .

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. In the drawings, the same reference numerals will be used for the same or corresponding members. In the drawings,
1 is a perspective perspective view of a bag according to an embodiment of the present invention;
2 is a block diagram of a product authentication system according to the present invention;
3 is a block diagram of an optical tag according to an embodiment of the present invention;
4 is a table showing an example of a color encoding process by the color encoder shown in FIG. 3;
5 is a table showing another example of a color encoding process by the color encoder shown in FIG. 3;
6 is a block diagram of one embodiment of an authentication terminal;
7 is a block diagram of one embodiment of an authentication server;
FIG. 8 is a flow diagram illustrating an activation process in the embodiment shown in FIGS. 3 to 7;
9 is a block diagram of an optical tag according to another embodiment of the present invention; And
FIG. 10 is a table illustrating an embodiment of an authentication code table shown in FIG. 9.

1 shows a bag 10 according to an embodiment of the present invention. According to a preferred embodiment, the bag 10 is provided with an optical tag 20 according to the present invention. In one embodiment, the optical tag 20 is attached to one side of the inner circumferential surface of the bag 10, or is embedded between the outer and the inner feel is installed only part exposed through the inner feel. However, in a modified embodiment, the optical tag 20 may be attached to the outside of the bag in a form suspended from the strap.

The optical tag 20 stores a product code, such as a product serial number assigned to the bag 10, or a plurality of authentication codes, and displays product authentication information corresponding to the product code or authentication code according to a user's operation. Can be output in the form To this end, the optical tag 20 includes one or more light emitting diodes (LEDs).

2 shows the product authentication system according to the present invention as a whole. The illustrated authentication system includes an authentication terminal 100 and an authentication server 150.

The authentication terminal 100 receives visible light emitted from the optical tag 20, detects product authentication information from the visible light, extracts an authentication code from the product authentication information, and requests the authentication server 150 to activate. Then, the authentication terminal 100 receives a response message from the authentication server 150, and displays whether the bag 10 is genuine or fixtures, or counterfeit goods.

The authentication server 200 stores product information and authentication codes for all bags produced or sold by a bag supplier in a database and provides an activation service according to a client's request. In addition, the authentication server 200 may additionally provide a service for registering and updating owner information in a database for each product. When the authentication request is received from the authentication terminal 100, the authentication server 200 determines whether the product related to the request is genuine by comparing the authentication code received with the authentication request or separately with the value stored in the database. In addition, the authentication server 200 includes the determination result in the response message and provides it to the authentication terminal 100.

3 is a block diagram of an optical tag 20 according to an embodiment of the present invention. The optical tag 20 according to the present embodiment includes a power supply unit 22, a storage unit 24, a switch 26, a code conversion unit 28, a color encoder 30, and a light emitting unit 32.

The power supply unit 22 supplies power to each part of the optical tag 20. In a preferred embodiment, the power supply 22 is implemented by a battery. However, in the modified embodiment, the power supply unit 22 may be an external connection terminal capable of receiving DC power from the outside only when necessary. In one embodiment, the external connection terminal may be a USB jack that can be connected to the authentication terminal 100 or other data terminal to receive power. However, in other embodiments, the external connection terminal may be a simple DC power supply terminal for receiving direct DC power directly through an adapter.

The storage unit 24 stores a product code, that is, a product serial number for the bag 10. The storage unit 24 also stores data relating to code conversion rules for the product code. In one embodiment, the code conversion data may be a lookup table (LUT) for converting each binary code, decimal code, or hexacode constituting the product code in a certain manner. However, in other embodiments, the transcoded data may be a predetermined polynomial coefficient. Such a storage unit 24 is implemented by a recordable storage device or a ROM such as a flash memory.

The switch 26 allows the user to control whether the optical tag 20 emits product authentication information in the form of visible light while the optical tag 20 is fed through the power supply 22. In a preferred embodiment, the optical tag 20 emits the visible light for a predetermined time from the moment when the switch 26 is pressed in the power feeding state. However, in the modified embodiment, visible light may be continuously emitted while the optical tag 20 is being fed.

The code conversion unit 28 reads the product code from the storage unit 24 and converts the product code into a data string having a different value according to the code conversion rule. In one embodiment, the code conversion unit 28 generates the authentication code by converting the product code into another data string in a predetermined manner based on the lookup table (LUT). However, in the modified embodiment, the code conversion section 28 performs a polynomial operation according to the coefficients stored in the storage section 24 on the product code to generate the authentication code.

The color encoder 30 encodes the authentication code generated by the code converter 28 into each color value of RGB. The light emitter 32 emits visible light according to the encoded color value. In a preferred embodiment, the light emitting unit 32 includes an LED driving circuit 34 and at least one assembly of three LEDs 36a to 36c for implementing red-green-blue (RGB) color. Here, the LED assembly may additionally be provided with a white LED 36d for implementing a white color. Prior to emitting visible light according to the encoded color value of the authentication code, the color encoder 30 outputs a predetermined test color value pattern, so that the authentication terminal 100 receives the received sensitivity of the LED 36a of the optical tag 20. And correction in synchronization with the light emission sensitivity of ˜36c). The test color value pattern can be such that, for example, all LEDs 36a to 36c simultaneously flash several times at a certain level, for example, RGB levels of "0x1C" and "0xE4".

4 shows an example of a color encoding process by the color encoder 30. In this example, it is assumed that the authentication code is a sequence of numbers constructed using numbers 0-9.

When quantizing each color of RGB in 256 steps in one tri-color LED, each of the RGB colors can represent 256 (= 2 ⁸ ) cases, and one tri-color LED assembly totals 16,777,216 (= 2 ²⁴ ) It may indicate the case of eggplant.

In the embodiment of Fig. 4, each of the two digits of the authentication code is represented by one of the colors of RGB. Specifically, when two digits of the authentication code to be color encoded are decimal "00", this code value is mapped to the color value of "0x1D", and the authentication code value "01" is mapped to the color value of "0x1F". , Authentication code value "02" is mapped to the color value of "0x21", authentication code value "03" is mapped to the color value of "0x23", authentication code value "04" is mapped to the color value of "0x25" do. When mapping in this manner, the authentication code value "99" is mapped to the color value of "0xE3".

As such, by using each of the color values in mapping each authentication code value to one color value, the possibility of recognition error in the authentication terminal 100 is reduced. In addition, the lowest 28 color values ("0x00" to "0x1C") and the highest 29 color values ("0xE4" to "0xFF") are not used for encoding the authentication code value. However, one of the lowest 28 color values ("0x00" to "0x1C") and one of the highest 29 color values ("0xE4" to "0xFF") may be selected from the authentication terminal 100. It can be used as a test color value for reception sensitivity synchronization and correction.

In this encoding, one tri-color LED assembly may represent a 6-digit decimal string, for example, if it is desired to represent a 24-digit string can be implemented using four LED assemblies.

5 shows another example of a color encoding process by the color encoder 30. In this example as well, the authentication code is assumed to be a string of numbers constructed using the numbers 0-9.

In the embodiment of Fig. 5, each digit of the authentication code is represented by one color of RGB. Specifically, when the authentication code digit to be encoded is decimal "0", this code value is mapped to the color value of "0x18", the authentication code value "1" is mapped to the color value of "0x2F". The authentication code value "2" is mapped to the color value of "0x46", the authentication code value "3" is mapped to the color value of "0x5D", and the authentication code value "4" is mapped to the color value of "0x74". . When mapping in this manner, the authentication code value "9" is mapped to the color value of "0xE7".

In this way, in mapping each authentication code place value to one color value, one by one while skipping 22 color values is reduced, thereby reducing the possibility of a recognition error occurring in the authentication terminal 100. In addition, the lowest 24 color values ("0x00" to "0x17") and the highest 24 color values ("0xE8" to "0xFF") are not used for encoding the authentication code value. However, one of the lowest 24 color values ("0x00" to "0x17") and the highest 24 color values ("0xE8" to "0xFF") can be used as the test color value. There is.

In this encoding, one tri-color LED assembly may represent a three-digit decimal number sequence at any point in time, and may represent a twelve-digit number sequence when four LED assemblies are used.

On the other hand, in the embodiment of Figures 4 and 5, the color value is mapped so as to increase linearly according to the authentication code place value, in the modified embodiment in consideration of the light emission characteristics of the LED (36a ~ 36d) It may be mapped to increase non-linearly according to the authentication code place value.

6 is a block diagram of one embodiment of an authentication terminal 100. The authentication terminal 100 includes a light receiving unit 102, a reception code recognition unit 104, a sensitivity synchronization / correction unit 106, an authentication processing unit 108, and a display 110. In the authentication terminal 100, the authentication terminal 100 may be a portable terminal such as a smartphone. However, in another embodiment, it may be a PC installed in a store, an agency, a service center, etc. of the bag 10 manufacturer. The reception code recognition unit 104 and the authentication processing unit 108 are implemented by an application program that runs on a portable terminal or a PC.

The light receiving unit 102 receives visible light emitted from the optical tag 20 and converts the visible light into an electric signal, and the reception code recognition unit 104 detects an authentication code from the converted electric signal.

In an embodiment in which a portable terminal such as a smartphone is used as the authentication terminal 100, the light receiving unit 102 may be a camera provided in the terminal. The camera may photograph around the LED assembly of the optical tag 20 while the program is running. The reception code recognition unit 104 detects a spectrum of visible light emitted from the LED assembly, for example, color components, from the camera image, and extracts an authentication code from the detected color component values.

On the other hand, in the embodiment where the PC or POS terminal is used as the authentication terminal 100, the light receiving unit 102 may be a scanner or a camera separately installed in the PC or POS terminal. The scanner detects visible light emitted from the LED assembly of the optical tag 20 while the program is running. The reception code recognition unit 104 detects color components of visible light emitted from the LED assembly from the detected visible light, and extracts an authentication code from the detected color component values.

The sensitivity synchronization / correction unit 106 transmits the received sensitivity to the light emitting sensitivity of the LED assembly of the optical tag 20 based on the test color value pattern outputted by the optical tag 20 before emitting the visible light encoded with the authentication code. In addition to the synchronization correction, the distortion of the optical signal due to the inflow of external illumination light is corrected.

The authentication processor 108 transmits the extracted authentication code to the authentication server 150 to request genuine authentication. In addition, the authentication terminal 100 receives a response message from the authentication server 150 and displays on the display 110 whether the bag 10 is a genuine product or a counterfeit product. In communication between the authentication terminal 100 and the authentication server 150, a key authentication type security system such as public key encryption may be added to increase security.

7 is a block diagram of one embodiment of an authentication server 150. The authentication server 150 includes an authentication code generation unit 152, a database 154, and a product authentication unit 160. The database 154 includes an authentication code table 156 and a product information table 158.

The authentication code generation unit 152 performs the same conversion operation that the code conversion unit 28 of the optical tag 20 performs on the product codes assigned to all products sold by the manufacturer of the bag 10. By doing so, an authentication code is generated, and the generated authentication code is stored in the authentication code table 156. The product information table 158 stores general attribute information of all products manufactured and sold by the bag 10 manufacturer.

When the authentication request is received from the authentication terminal 100, the product authentication unit 160 determines whether the product related to the request is genuine by comparing the authentication code received with the authentication request or separately with the authentication code stored in the database. In addition, the product authentication unit 160 includes the determination result in the response message and provides the result to the authentication terminal 100.

FIG. 8 shows a genuine product certification process in the embodiment shown in FIGS. 3 to 7.

First, a user or purchaser who wants to activate the product for his bag 10 visits a manufacturer, a dealer, or a service center of the manufacturer of the bag 10 and requests a genuine confirmation inquiry. An employee working at a store or the like connects the USB terminal of the optical tag 20 of the bag 10 to the authentication terminal 20, that is, the workplace PC so that the power can be supplied to the optical tag 20 (step 200). . When the genuine product certification program of the present invention is installed in a user's smartphone or PC, the user may directly connect the optical tag 20 to his authentication terminal 20, that is, the smartphone or PC.

In this state, the operator of the authentication terminal 20 drives the activation program and turns on the switch 26 of the optical tag 20 (step 202). When the switch 26 is turned on, the color encoder 30 of the optical tag 20 outputs a predetermined test color value pattern so that the light emitter 32 emits light for the test color value pattern (step 204). . The sensitivity synchronization / correction unit 106 of the authentication terminal 100 that detects the test color emitted according to the test color value pattern adjusts the color component detection criteria according to the detected test color, thereby receiving sensitivity in the entire visible light region. (Step 206).

Subsequently, the color encoder 30 of the optical tag 20 encodes the authentication code generated by the code converter 28 into respective color values of RGB, and the light emitter 32 displays visible light according to the encoded color values. To light. Accordingly, visible light is emitted in a color corresponding to the authentication code (step 208).

In operation 210, the light receiving unit 102 of the authentication terminal 100 receives visible light emitted from the optical tag 20 and converts the visible light into an electrical signal. The reception code recognition unit 104 restores the authentication code according to the RBG color value using the converted electric signal (step 212).

Subsequently, the authentication processing unit 108 of the authentication terminal 100 transmits the restored authentication code to the authentication server 150 to request activation, and receives a response message indicating whether the bag 10 is a genuine product or a counterfeit product. Display on the display 110 (step 214). In the communication between the authentication terminal 100 and the authentication server 150, it is desirable to maintain security.

The information displayed on the display 110 includes a product code, that is, a product serial number, and additional information about the corresponding product, for example, the date of shipment or the owner currently registered on the authentication server 150, together with information on whether the product is genuine. can do.

9 is a block diagram of an optical tag 20 according to another embodiment of the present invention.

In this embodiment, the authentication code storage unit 324 stores the authentication code table 325 including a plurality of authentication codes generated in advance for the bag 10. 10 shows an embodiment of the authentication code table 325. In the illustrated embodiment, the authentication code table 325 stores 100 authentication codes, but the present invention is not limited to the number of such authentication codes. The authentication code table 325 is preferably stored in the database 154 of the authentication server 150 in the same manner.

Each time a user attempts to activate, the authentication code selection unit 328 selects one of a plurality of authentication codes stored in the authentication code storage unit 324 and provides it to the color encoder 30. Authentication codes are chosen at irregular intervals according to predetermined rules. In the example of FIG. 10, after the first authentication code CODE # 00 is selected, the fourth authentication code CODE # 03 is selected, then the sixth authentication code CODE # 05 is selected, and then the tenth authentication. Code CODE # 09 is shown to be selected.

Each time an activation request is received, the authentication server 150 selects an authentication code from the database 154 according to the same rules as applied to the authentication code selector 328 of the optical tag 20, and compares the two. Perform authentication. Here, when the authentication operation is stopped before the authentication server 150 receives the authentication request, the authentication code selected from the optical tag 20 and the authentication code read from the database 154 of the authentication server 150 may not be the same. Can be. In view of this, the authentication server 150 may read a plurality of authentication codes from the database 154 according to the rule, and compare each of the plurality of authentication code candidates with the authentication code received through the authentication terminal 100. On the other hand, if the authentication code received through the authentication terminal 100 is the same as the code previously used for authentication, or the code stored in front of the code used for the most recent authentication, the authentication server 150 is the corresponding authentication The code may be regarded as illegally copied, and an authentication response message indicating that the corresponding product is a counterfeit product may be provided to the authentication terminal 100.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

For example, although the authentication of the product has been described above with reference to the bag, the present invention is not limited thereto, and the present invention may be used for authenticating other products. In addition, the present invention can be widely used not only to recognize whether a product is genuine but also to check general information about the product.

On the other hand, in the above, the number of times of authentication is not mentioned separately, but the authentication method of the present invention may limit the number of times for each product. For example, in the embodiment of FIG. 9, authentication may continue until the authentication code finally available in the authentication code table 325 is used. Also in the embodiment shown in Figure 3, the number of authentications for each product may be limited within a certain range. In such a case, it is preferable to guide the buyer separately about the number of times that the product can be authenticated at the time of selling the product.

On the other hand, in the above, when it is determined that the product received the inquiry request is a counterfeit product, only the message indicating that the counterfeit goods is provided to the authentication terminal 100, but in the modified embodiment, in this case, the optical tag Additional measures may be taken to delete or otherwise invalidate the product code or certification code stored in (20). To this end, the genuine product certification program preferably has a function of deleting or invalidating the product code or the authentication code while the authentication terminal 100 is connected to the optical tag 20 through the USB cable.

On the other hand, the above description has been mainly focused on the embodiment in which the optical tag displays the authentication information in full color colors of RGB. However, in another embodiment, the optical tag may display the authentication information only at a single color, for example, a white color level. have. In such a case, the 'spectrum information' in the present specification may be a level value or light intensity at a specific frequency (s).

On the other hand, while the above has been described with reference to the embodiment in which one optical tag has one RGB LED assembly, as mentioned above, several RGB LED assemblies may be used. In this case, the plurality of RGB LED assemblies may sequentially emit light corresponding to the authentication information, and may simultaneously emit light. When a plurality of RGB LED assemblies emit light at the same time, it is preferable that the authentication terminal can separately receive light at a position corresponding to each RGB LED assembly.

Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

Claims (20)

A tag device that can be attached to a product,
A spectral encoder for generating spectral information according to a unique code of a product; And
A light emitting unit for emitting a visible light authentication signal according to the spectrum information;
Optical tag device having a. The method according to claim 1,
The spectral encoder determines each color value of RGB according to the unique code,
And the light emitting part emits the visible light authentication signal according to the determined color values. The method according to claim 2,
And a test ray pattern for correcting sensitivity of an authentication terminal before the light emitting unit emits the visible ray authentication signal. The method according to claim 2,
A storage unit for storing the unique code;
Optical tag device further comprising. The method of claim 4, wherein the unique code stored in the storage unit is a product serial number for the product,
A code conversion unit generating an authentication code based on the product serial number by a predetermined technique;
Further comprising:
And the spectrum encoder determines the color values according to the authentication code. The method of claim 4, wherein the unique code stored in the storage unit is a plurality of authentication codes,
And the spectrum encoder determines the color values according to any one selected from the plurality of authentication codes. The method of claim 6, wherein the unique code stored in the storage unit is a plurality of authentication codes,
A code selector configured to determine the selected code among the plurality of authentication codes;
Optical tag device further comprising. The method according to claim 2,
An external switch for controlling the operation of the spectrum encoder and the light emitting unit;
Optical tag device further comprising. The method according to claim 2,
An external connection terminal for receiving DC power from the outside;
Optical tag device further comprising. (a) generating spectrum information according to a unique code of a product; And
(b) outputting a visible light authentication signal according to the spectrum information;
Product authentication information generation method comprising a. The method of claim 10, wherein in step (a), each color value of RGB is determined according to the unique code.
In the step (b), the product authentication information generation method for outputting the visible light authentication signal in accordance with the determined color values. The method of claim 11, wherein step (b)
Outputting a test light pattern for correcting sensitivity of an authentication terminal before outputting the visible light authentication signal;
Product authentication information generation method further comprising. The method according to claim 11, wherein the unique code is a product serial number for the product,
Step (a)
Generating an authentication code by a predetermined technique based on the product serial number; And
Determining the color values according to the authentication code;
Product authentication information generation method further comprising. The method of claim 11,
Before performing step (a), storing a plurality of authentication codes as a unique code in a storage device;
Further comprising:
And in the step (a), determining the color values according to any one selected from the plurality of authentication codes. An authentication terminal for authenticating a tagged product that emits a visible light authentication signal that varies in spectrum according to a unique code of the product,
display;
A light receiving unit receiving the visible light authentication signal;
A reception code recognition unit for recovering the unique code from the spectrum of the visible light authentication signal; And
An authentication unit which provides the unique code to an authentication server to request authentication, receives an authentication response message, and outputs the received authentication response message through the display;
Authentication terminal having a. The method according to claim 15,
And the reception code recognition unit determines each color value of RGB from the visible light authentication signal, and determines the unique code according to the color value. 18. The method of claim 16,
A sensitivity correction unit for determining a test color value from a test light pattern received before the visible light authentication signal is received, and adjusting the reception sensitivity of the visible light authentication signal based on the test color value;
Product authentication terminal further comprising. A program that can be executed by a data terminal,
Receiving a visible light authentication signal emitted from a tag attached to a product;
Restoring a unique code of the product from the spectrum of the visible light authentication signal; And
Providing the unique code to an authentication server to request authentication, and receiving and outputting an authentication response message on a display;
A computer readable recording medium having recorded thereon a program for implementing the program. 19. The method of claim 18,
The computer-readable recording medium having recorded thereon a program for determining each color value of RGB from the visible light authentication signal and determining the unique code according to the color value in performing the receiving function. 19. The method of claim 18,
Determining a test color value from a test light pattern received before the visible light authentication signal is received, and adjusting reception sensitivity of the visible light authentication signal based on the test color value;
A computer-readable recording medium having recorded thereon the program further comprising.

Images