KR20100041649A - Sensor tag and method for authenticating for the same - Google Patents

Abstract

PURPOSE: A sensor tag device and an authentication method thereof are provided to tighten the security of RFIG tag by authenticating the RFID tag through a value corresponding to sensor device and to protect RFID or SID(Smart/Serial/Secure Identifier) sensor tag information by installing an authentication module in a sensor tag. CONSTITUTION: An RFID(Radio Frequency Identification) sensor tag device(1) comprises an RF(Radio Frequency) interface unit(11), a control unit(12) and a sensor unit(13). The sensor unit senses surrounding environment elements. The sensor unit outputs a sensing value. If physical change is in the sensor tag, the control unit blocks the use of the sensor tag through an initial value and current value. When the sensor tag is attached to a product, the initial value is sensed through the sensor unit. The current value is sensed through the sensor unit.

Description

Sensor tag device and its authentication method {Sensor tag and method for authenticating for the same}

The present invention relates to a sensor tag device and an authentication method thereof, and more particularly, to a radio frequency identification (RFID) tag device or an smart identification (Smart / Serial / Secure IDentifier, SID) tag device and a method for authenticating the same. It is about.

The present invention is derived from the research conducted as part of the IT growth engine core technology development project of the Ministry of Knowledge Economy and the Ministry of Information and Communication Research and Development. [Task management number: 2006-S-041-03, Task name: Security and Development of common security core module for trust service.

The RFID or SID sensor tag may be applied to various fields such as product identification or vehicle identification. An RFID or SID sensor tag attached to a product stores data about the product and the buyer. RFID or SID sensor tags can also be embedded in product packaging, library books, credit cards, identification cards, driver's licenses and passports. By attaching an RFID or SID sensor tag to the article, it can be utilized for article management, prevention of forgery and alteration of the article, and measurement control.

Authentication is required for the RFID or SID sensor tag to prevent illegal use of the above-described identification service and to prevent forgery of RFID or SID sensor tag information.

An object of the present invention is to provide a sensor tag device for protecting RFID or SID sensor tag information by providing a module for authentication in a sensor tag, and an authentication method thereof.

According to an aspect of the present invention, there is provided a sensor tag attached to an article, the sensor unit sensing a surrounding environment element to output a value; And when it is determined that there is a physical change in the sensor tag by using the initial value sensed through the sensor unit and the current value sensed through the sensor unit when the sensor tag is attached to the article, the sensor tag may not be used. And a control unit for processing.

According to an aspect of the present invention, there is provided a method of authenticating a sensor tag, comprising: sensing a surrounding environment through a sensor unit when a sensor tag is attached to an article, and storing the sensed value as an initial value internally or externally; When receiving an authentication request from the outside, sensing the current surrounding environment to generate a current value; If the initial value is stored therein, comparing the initial value with the current value to determine whether there is a physical change in the sensor tag; And if the initial value is stored externally, outputting the current value to the outside to determine whether there is a physical change in the sensor tag by comparing the initial value with the current value from the outside.

According to the present invention, security of an RFID tag can be enhanced by authenticating the RFID tag using a value output corresponding to the device from a sensor device embedded or external to the RFID sensor tag. In addition, it is possible to determine the authenticity of the product to which the RFID tag is attached, and to prevent the forgery of the tag itself.

In addition, it is possible to prevent the forgery of the terminal by embedding the SID sensor tag in various terminal devices, and can be used in the field of measurement control by connecting the SID sensor to various terminals.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to those skilled in the art to fully understand the present invention, and may be modified in various forms, and the scope of the present invention is limited to the embodiments described below. no. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention. Like parts are designated by like reference numerals throughout the specification.

1 is a block diagram of an RFID sensor tag device 1 according to an embodiment of the present invention. The illustrated RFID sensor tag device 1 includes an RF interface unit 11, a control unit 12, and a sensor unit 13.

The RF interface unit 11 converts the received RF signal into digital data to extract information included in the RF signal, or converts necessary data into an RF signal and transmits it. The controller 12 controls the operation of each component. The sensor unit 13 outputs data using a signal output from a sensor (not shown) located inside or outside the RFID sensor tag 1. The sensor may be implemented using sensor elements whose values change according to an external environment such as temperature, pressure, humidity, acceleration, light, contact, bio, or the like, or may be implemented as elements having a fixed value.

In addition, the display unit for displaying data to determine the state of the tag with the naked eye according to the tag operation in the form of a storage unit 14 for data storage, serial interface unit 15 for interworking with external devices, LED as needed ( 16) or may further include a security unit for data security.

For example, for pure water measurement, the RFID sensor tag 1 is sufficient only by the RF interface unit 11, the control unit 12, and the sensor unit 13. However, if you want to know the environmental characteristics of the RFID sensor tag 1, the display unit 16 can be added to examine. As a simple example, the state of the article attached to the RFID sensor tag 1 can be identified by including the LED as the display unit 16 and determining the state of the RFID sensor tag 1 by the color of the LED. As such, the display unit 16 may be adopted as a device that can sense the human body through various sensory organs (eye, touch, and smell). For example, the above-described LED or a device capable of sensing and displaying at the same time, for example, may be a device that the sensor reacts to generate aroma as the surrounding environment changes, or that the sensor can be deformed by itself to feel sensationally. have.

In order to emphasize the security, a security unit 17 for securing the data may be further added by decrypting the information extracted from the RF signal or encrypting the data to be transmitted in the RF signal. Therefore, the RFID sensor tag 1 can be utilized in a wide variety of applications by further connecting the components as needed.

The serial interface unit 15 may be used as a path for providing the information of the RFID sensor tag 1 to the outside or receiving from the outside, and may interwork with an external device without passing through the RF interface unit 11.

FIG. 2A illustrates a communication structure including the RFID sensor tag device 1 of FIG. 1. As shown, the RFID sensor tag 1 communicates with an RFID reader.

The illustrated reader is a mobile reader, but may also be implemented in the form of a smart card. In addition, the RFID reader may communicate with the server 4 connected to the wireless network 3 via the portable terminal 2. In this case, the wireless network 4 may be a Ubiquitous Sensor Network (USN). In this case, the server 4 may be a USN system server or a storage device corresponding to a reader, and the storage device may be a memory.

While communicating with the RFID sensor tag 1, the RFID reader authenticates identification information stored in the RFID sensor tag 1 and performs encryption and decryption on information necessary for communication with the RFID sensor tag 1. Here, the RFID reader may further include a display for visually checking the identification information and the forgery prevention of the RFID sensor tag 1. The RFID reader may further include function keys for selecting various functions such as a communication function with the outside. Representative readers satisfying these conditions can be easily used by realizing mobile readers that are currently available.

The RFID sensor tag 1 may embed or external the sensor unit 13 and may be used for authentication of an article. When the RFID sensor tag (1) is attached to articles such as medicines, agricultural products, art works, passports, money, etc., the RFID sensor tag (1) can be used if the sensor is physically deformed or destroyed or forged. It becomes impossible to determine whether the goods are authentic or counterfeit.

As a specific example, by attaching the RFID sensor tag 1 to a currently used passport, it is possible to manage forgery and alteration of the passport. In other words, it is easy to determine if physical damage is done to forge the electronic passport. Anyone who wants to forge and tamper with an e-passport will have no choice but to physically touch the passport, thus damaging the sensor with a random value in the passport. Therefore, if the passport is used, the unique value of the passport and the initial sensor value stored at the time of issuance are different, and the RFID reader detects this and determines whether the forgery is forged. Here, the place where the initial sensor value is stored may be a memory in the RFID sensor tag 1 of the electronic passport itself, a storage device in the reader, and a server 4 connected to the wireless network 3.

Another example would be managing safe agricultural products, medicines, art and beverages. In other words, genuine brand management. In order to safely manage these goods, the sensor unit 13 of the RFID sensor tag 1 may use a bio or contact sensor. If there is an article that should be stored at room temperature at all times, it is possible to determine whether the safety management of the product has been carried out by using a device such as a biosensor that maintains a constant value at room temperature and deforms the sensor value outside the temperature. .

2b and 2c illustrate the medical and agricultural products to which the RFID sensor tag 1 is attached, respectively.

FIG. 2D illustrates another embodiment of a communication structure including the RFID sensor tag device 1 of FIG. 1. As shown, the mobile terminal 1-a serves as one RFID sensor tag and communicates with the tag reader 2-a. However, the mobile terminal 1-a to which the RFID sensor tag 1 is attached may be connected to the mobile wireless network 3-a to realize a service by itself. That is, a scenario of a mobile sensor tag can be configured without a separate RFID reader.

3A and 3B are flowcharts illustrating a method of issuing and authenticating the RFID sensor tag 1 when the sensor initial value is stored in the RFID sensor tag 1.

According to FIG. 3A, in the process of issuing an RFID sensor tag 1, first, when the RFID reader 2 requests a sensor initial value from the RFID sensor tag 1 (31), the RFID sensor tag 1 may be a sensor unit ( 13, the current state is sensed (step 32), and the sensed value is set as an initial value and stored in the storage unit 14 (step 33). After storage, the sensor initial value is output to the RFID reader 2. (Step 34).

According to FIG. 3B, in the process of authenticating the RFID sensor tag 1, first, when the RFID reader 2 queries the RFID sensor tag 1 for authentication (step 35), the RFID sensor tag 1 is connected to a sensor unit ( 13, the current state is sensed (step 36), and the detected value is compared with the initial value stored in the storage unit 14 to determine whether to authenticate (step 37). Authentication is determined based on whether the initial value and the current sensed value are outside a predetermined allowable range. Next, the RFID sensor tag 1 outputs the authentication result to the RFID reader 2 (step 38).

4A and 4B are flowcharts illustrating a method of issuing and authenticating the RFID sensor tag 1 when the sensor initial value is stored in the RFID reader 2 side.

According to FIG. 4A, when the RFID reader 2 requests a sensor initial value from the RFID sensor tag 1 (step 41), the RFID sensor tag 1 senses a current state through the sensor unit 13 ( In step 42, the detected value is set as an initial value and transmitted to the RFID reader 2 (step 43). The RFID reader 2 stores the received initial value in a memory provided inside, a Trusted Platform Module (TPM) or a secure digital (SD) card, a universal serial bus (USB) memory, a smart card, etc. (step 44). ).

According to FIG. 4B, the process of authenticating the RFID sensor tag 1 is as follows. First, when the RFID reader 2 queries the RFID tag sensor 1 for authentication information (step 45), the RFID sensor tag 1 senses the current state through the sensor unit 13 (step 46). The value is transmitted to the RFID reader 2 as authentication information (step 47). The RFID reader 2 compares the initial value stored in the internal or external memory with the authentication information received from the RFID sensor tag 1 and determines whether to be authenticated (step 48). When the RFID reader 2 requests tag processing to the RFID sensor tag 1 according to the authentication result after the authentication (step 49), the RFID sensor tag 1 maintains its current state when it is authenticated. If not authenticated, the process is processed so as not to reuse (step 50), and the result is output to the RFID reader 2 (step 51). In this case, the reuse prevention process may be an electrical breakdown, a hardware lock, or the like.

5A and 5B are flowcharts illustrating a method of issuing and authenticating an RFID sensor tag 1 when the sensor initial value is stored in the server 4 connected to the wireless network 3.

As shown in FIG. 5A, when the RFID reader 2 requests the sensor initial value from the RFID sensor tag 1 (step 51), the RFID sensor tag 1 is connected to the sensor unit 13. After sensing the current state through the step (52), the sensed value is set as an initial value and transmitted to the RFID reader 2 (step 53). The RFID reader 2 transmits the received initial value to the server 4 while requesting to store the received initial value in the server 4 (step 54). The server 4 stores the received initial value (step 55) and outputs the stored initial value to the RFID reader 2 (step 56).

The authentication process according to FIG. 5B is as follows. First, when the RFID reader 2 queries the RFID tag sensor 1 for authentication information (step 57), the RFID sensor tag 1 senses the current state through the sensor unit 13 (step 58). The value is transmitted to the RFID reader 2 as authentication information (step 59). The RFID reader 2 requests authentication from the server 4 while transmitting the received authentication information to the server 4 (step 60). The server 4 compares the initial value stored in advance with the received authentication information to determine whether to authenticate (step 65), and outputs the authentication result to the RFID reader 2 (step 61). When the RFID reader 2 requests tag processing from the RFID sensor tag 1 according to the authentication result (step 62), the RFID sensor tag 1 maintains its current state when it is authenticated. If not authenticated, the process is not reused (step 63), and the result is output to the RFID reader 2 (step 64).

In the process of authenticating the above-described RFID sensor tag 1, when the authentication is performed by the RFID reader 2 or the server 4, the RFID sensor tag 1 may not include the storage unit 14. In this case, the advantage is that when the memory is inserted into the tag 1, the tag area is increased, power consumption is increased, and chip price and operation performance may be affected.

6 is a detailed block diagram of the RF interface unit 11 of the RFID sensor tag 1 according to the present invention. The illustrated RF interface unit 11 is further provided with a second regulator for stably supplying power to the RFID sensor tag 1.

The RF interface unit 11 modulates a demodulation unit for demodulating a received signal or modulates a transmission signal or a demodulation unit 111 for demodulating or modulating a transmission signal, a clock unit 112, a protection unit 113, and a power supply unit 114. Include. The power supply unit 114 includes a rectifier 1141 for rectifying the received RF signal, a first regulator 1142 for outputting a first DC signal, and a second regulator 1143 for outputting a second DC signal.

In the use of the RFID sensor tag 1, the voltage supplied to the sensor unit 13 may fluctuate depending on the distance between the RFID sensor tag 1 and the RFID reader 2 or the instantaneous power consumption change in the RFID sensor tag 1. Can be. When the shaking DC voltage is supplied to the sensor unit 13, the measured values may appear differently each time it is sensed. At this time, the controller 12 recognizes that the physical hacking has occurred because the sensing value is shaken, and can switch the tag itself to prevent reuse. Therefore, a stable second power source is required, and if the second recirculator 1143 is added, the power source can be stabilized to obtain an accurate sensor value. The first regulator 1142 supplies power to the digital part of the RFID sensor tag 1, and the second regulator 1143 that outputs more stable power supplies power to an analog part such as the sensor part 13. Can be supplied

The first regulator 1142 outputs a DC voltage of about 3.3V from the rectified RF signal output from the rectifier 1141, and the second regulator 1143 is about 1.8V from the output of the first regulator 1142. Output DC voltage. The first regulator 1142 is configured to output a DC voltage from the rectified RF signal having a wide input signal range, and the second regulator 1143 is an ambient environment such as a temperature with respect to the output voltage of the first regulator 1142. Stable voltage is output by precisely adjusting the voltage so as not to be affected by the fluctuation factor of.

7 is a block diagram of an SID sensor tag 7 which is another embodiment of the present invention. The illustrated SID sensor tag 7 includes an I / O interface 71, a control unit 12, and a sensor unit 13, in addition to the storage unit 14, the display unit 16, and the security unit 17 as necessary. It may be further provided. The operation is the same as the RFID sensor tag 1 shown in FIG. 1 except that the signal processed by the I / O interface 71 is a data signal rather than an RF signal.

The SID sensor tag 7 communicates using a serial interface. Accordingly, the I / O interface 71 may be a universal asynchronous receiver / transmitter (UART), USB, inter-IC (I2C), general purpose input / output (GPIO), or the like.

8 is a block diagram of the I / O interface unit 71 of the SID sensor tag 7. The illustrated I / O interface unit 71 includes a power switch 711 and a regulator 712.

The I / O interface unit 71 may further include a power switch 711 and a regulator 712 to supply stable power to the sensor unit 13 to stabilize external power. If the sensor unit 13 is not used, the recurator 712 may not be used through the power switch 711 to reduce power consumption.

9 illustrates a communication structure including the SID sensor tag device 7 of FIG. 7.

As shown, the SID sensor tag 7 is embedded in the mobile terminal 8, and the mobile terminal 8 communicates with the server 4 via the wireless network 3. If the SID sensor tag 7 is used for authentication, after the sensor unit 13 attaches the built-in or external SID sensor tag 7 to the article, the sensor unit 13 is physically deformed or destroyed, or In the case of forging the SID sensor tag 7, the SID sensor tag 7 cannot be used, which is effective in determining the authenticity of the article.

The application example of the SID sensor tag 7 is the same as the application example of the RFID sensor tag 1 shown in FIG.

As another application of the SID sensor tag 7, the SID sensor tag 7 is embedded in a memory device 10 or a terminal such as a USB memory or a secure digital (SD) card as shown in FIG. As shown, since the SID sensor tag 7 exists in the memory device 10 or the terminal, the forgery state of the memory device 10 or the terminal itself can be directly authenticated by the SID sensor tag 7.

11 illustrates a process of issuing and authenticating the SID sensor tag 7 when the initial value is stored in the SID sensor tag 7.

First, the SID sensor tag 7 senses the current state through the built-in or external sensor unit 13 (step 111), and stores the detected initial value in the SID sensor tag 7 (step 112). In the case of authentication, the sensor unit 13 senses the current state again (step 113), and compares the previously stored initial value with the current sensed value and authenticates it (step 114). It may be determined whether to reuse the SID sensor tag 7 according to the authentication result.

12A and 12B illustrate an issuance and authentication process of the SID sensor tag 7 when the initial value is stored in the terminal having the SID sensor tag 7 embedded therein.

According to FIG. 12A, first, the server 4 requests a sensor initial value from the terminal 8 or the memory device 10 to which the SID center tag 7 is connected or includes the SID sensor tag 7 (step 121). . The terminal 8 or the memory device 10 senses the current state value (step 122), and stores an initial value therein (step 123). In this case, a storage device (not shown) inside the terminal 8 may be a TPM, an EEPROM, or a flash memory, and the memory device 10 may be a USB memory, an SD card, or a Universal Subscriber Identity Module (USIM) card. Or a smart card. Next, the terminal 8 or the memory device 10 transmits the sensor initial value to the server 4 (step 124).

In the authentication process according to FIG. 12B, when the server 4 queries the terminal 8 or the memory device 10 for authentication (step 125), the terminal 8 or the memory device 10 senses a current state ( Step 126), the previously stored initial value and the current sensed value are compared and authenticated (step 127), and the authentication result is returned to the server 4 (step 128).

13A and 13B illustrate a process of issuing and authenticating the SID sensor tag 7 when the sensor initial value is stored in the server 4.

According to FIG. 13A, the server 4 requests the sensor initial value from the terminal 8 or the memory device 10 to which the SID center tag 7 is connected or includes the SID sensor tag 7 (step 131). . The terminal 8 or the memory device 10 senses the current state value (step 132), and then transfers the sensed value to the server 4 (step 133). The server 4 stores the received initial value (step 134).

In the authentication process according to FIG. 13B, when the server 4 queries the terminal 8 or the memory device 10 for authentication (step 135), the terminal 8 or the memory device 10 senses a current state. Next, the sensed value is transmitted to the server 4 (step 137). The server 4 authenticates by comparing the previously stored initial value and the currently received value (step 138), notifies the authentication result to the terminal 8 or the memory device 10, and the SID sensor tag 7 according to the authentication result ), The process requests (step 139). The terminal 8 or the memory device 10 reuses the SID sensor tag 7 if the authentication is successful, and if the authentication fails, the SID sensor tag 7 is not reused. The processing of

The invention can also be embodied as computer readable code. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD_ROM, magnetic tape, floppy disks, optical data storage devices, and the like, and also include those implemented in the form of carrier waves, for example, transmission over the Internet. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

As described above, optimal embodiments have been disclosed in the drawings and the specification. Herein, specific terms have been used, but they are used only for the purpose of illustrating the present invention and are not intended to limit the scope of the present invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a block diagram of an RFID sensor tag device according to an embodiment of the present invention.

FIG. 2A illustrates a communication structure including the RFID sensor tag device of FIG. 1.

2B and 2C illustrate medical and agricultural products each having an RFID sensor tag attached thereto.

3A and 3B are flowcharts illustrating a method of issuing and authenticating an RFID sensor tag when the sensor initial value is stored in the RFID sensor tag.

4A and 4B are flowcharts illustrating a method of issuing and authenticating an RFID sensor tag when the sensor initial value is stored on the RFID reader 2 side, respectively.

5A and 5B are flowcharts illustrating a method of issuing and authenticating an RFID sensor tag when the sensor initial value is stored in a server connected to the wireless network 3.

6 is a detailed block diagram of the RF interface unit of the RFID sensor tag according to the present invention.

7 is a block diagram of an SID sensor tag according to another embodiment of the present invention.

8 is a block diagram of an I / O interface unit of the SID sensor tag.

FIG. 9 illustrates a communication structure including the SID sensor tag device of FIG. 7.

10 shows another application example of the SID sensor tag.

11 illustrates a process of issuing and authenticating an SID sensor tag when an initial value is stored in the SID sensor tag.

12A and 12B illustrate a process of issuing and authenticating the SID sensor tag when the initial value is stored in the terminal having the SID sensor tag embedded therein.

13A and 13B illustrate a process of issuing and authenticating an SID sensor tag when storing an initial sensor value in a server.

Claims (10)

A sensor tag attached to an article, A sensor unit for sensing a surrounding environment element and outputting a value; And When it is determined that there is a physical change in the sensor tag using the initial value sensed through the sensor unit and the current value sensed through the sensor unit when the sensor tag is attached to the article, the sensor tag is not used. Sensor tag, characterized in that it comprises a control unit. The method of claim 1, The sensor tag is an RFID sensor tag that communicates with an RFID reader through an RF signal, or a sensor tag connected to a first server or embedded in a portable device. The method of claim 2, The RFID sensor tag or the SID sensor tag further includes a storage unit to store the initial value in the storage unit, wherein the RFID sensor tag is stored from the RFID reader or the SID sensor tag is stored from the first server or the portable device. And receiving one signal, comparing the initial value with the present value to determine whether there is a physical change in the sensor tag. The method of claim 2, In the RFID sensor tag, the controller outputs the initial value and the present value to the RFID reader, and receives a comparison result of the initial value and the present value from the RFID reader to determine whether there is a physical change in the RFID sensor tag. and, In the SID sensor, the controller outputs the initial value and the current value to the first server or the portable device, and receives the comparison result of the initial value and the current value from the first server or the portable device. Sensor tag, characterized in that determining whether there is a physical change in the tag. The method of claim 4, wherein The RFID reader stores the initial value in advance in a storage device provided therein or a storage device connected to the RFID reader, and when the current value is received, compares the stored initial value with the current value and outputs the result to the RFID sensor tag. Or outputting the initial value and the present value to a second server, receiving a comparison result of the initial value and the present value from the second server, and transferring the result to the RFID sensor tag. The method of claim 2, The RFID sensor tag further includes an RFID interface between the controller and the RFID reader. The RFID interface is A rectifier for rectifying the RF signal received from the RFID reader; A first regulator adjusting a signal output from the rectifier to a first DC voltage; And And a second regulator for stabilizing the first DC voltage to adjust the second DC voltage to reflect a surrounding environment characteristic. The method of claim 2, The SID sensor tag further includes an SID interface between the controller and the server, wherein the SID interface A regulator for stabilizing an external power source and adjusting the voltage to a second voltage; And And a power switch for selectively outputting the second voltage as needed in addition to the external power source. The method of claim 1, The controller outputs the initial value and the present value to the outside, and receives a result of comparing the initial value and the present value from the outside to determine whether there is a physical change in the sensor tag. The method according to any one of claims 1 to 8, The sensor tag may include a security unit that encrypts at least one of the initial value and the current value; A serial interface for interworking with the outside; And And at least one of a display unit configured to display the state of the sensor tag according to the sensor tag operation. Sensing the surrounding environment through the sensor unit when the sensor tag is attached to the article, and storing the sensed value internally or externally as an initial value; When receiving an authentication request from the outside, sensing the current surrounding environment to generate a current value; If the initial value is stored therein, comparing the initial value with the current value to determine whether there is a physical change in the sensor tag; And And if the initial value is stored externally, outputting the current value to the outside and comparing the initial value with the current value from the outside to determine whether there is a physical change in the sensor tag. Tag verification method.

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