JP2008287534A - Wireless tag, interrogator, and management system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the security by discriminating an interrogator, and changing the response mode. <P>SOLUTION: A wireless tag management system 1 is provided with a reader 17 as an interrogator to a wireless tag circuit element To of a wireless tag T. The reader 7 is provided with a control part 11 and an antenna unit 12. The control part 11 generates a tag ID reading command signal and a discrimination command signal, including reader ID unique for the reader 7, and transmits these command signals in different timings via the antenna unit 12. A wireless tag circuit To is provided with an antenna 151 and an IC circuit part 150 connected to the antenna 151. The IC circuit part 150 decides whether the tag ID reading command signal and the discrimination command signal from the reader 7 have been received, and changes the configurations of a response to the tag ID reading command signal, according to the reader ID. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless tag including a wireless tag circuit element capable of wireless communication of information with the outside, an interrogator that performs signal transmission / reception with the wireless tag circuit element, and a management system including the wireless tag and the interrogator. It is.

  There is known an RFID (Radio Frequency Identification) system for reading / writing information in a non-contact manner between a small wireless tag and a reader (reading device) / writer (writing device) as an interrogator. The wireless tag circuit element provided in the wireless tag includes an IC circuit unit that stores predetermined wireless tag information and an antenna that transmits and receives information. It is possible to access (read / write information) information stored in the IC circuit section from the interrogator side, and practical use has already progressed in various fields such as product management and inspection processes.

  As one of wireless communication systems using wireless tags that are being used in various fields as described above, there is a wireless tag information reading system having an interrogator that reads information from a plurality of wireless tag circuit elements by wireless communication. Yes (see, for example, Patent Document 1). In this RFID tag information reading system, when the interrogator transmits inquiry signals to a plurality of RFID tag circuit elements, response signals are transmitted from the RFID tag circuit elements existing in the communication range to the interrogator. The information of the RFID tag circuit element is read.

JP-A-11-149530

  For example, a case where the above-described conventional technique is used for the movement management / entrance / exit management of articles and persons can be considered. In this case, an inquiry signal is transmitted to the RFID tag circuit element of the RFID tag attached to the article or carried by a person. Then, by reading information from the RFID circuit element in response to the response signal, it is possible to manage that the corresponding article or person has gone out, entered or moved.

  Here, when it is desired to perform the above-mentioned movement management / in / out management of articles / persons in a plurality of areas or a wide area, inquiry signals from a plurality of interrogators to a number of target RFID circuit elements. And information reading is executed at each. At this time, from the viewpoint of security, for example, there is a case where it is desired to change the response mode for each RFID circuit element according to the interrogator, for example, to respond only to a specific interrogator. In the above prior art, no particular consideration has been given to improving security by identifying such an interrogator and changing the response mode.

  An object of the present invention is to provide a wireless tag, an interrogator, and a management system that can improve security by identifying an interrogator and changing a response mode.

  In order to achieve the above object, the first invention includes a wireless tag circuit element including an IC circuit unit that stores information and a tag-side antenna that transmits and receives information, and the IC circuit unit includes an interrogator. Whether the identification command signal including the individual identification information unique to the interrogator is received by the tag side antenna at the second timing before or after the first timing at which the inquiry command signal of the tag is received by the tag side antenna It is characterized by comprising determination means for determining

  In the wireless tag according to the first aspect of the present invention, the determination means is provided in the IC circuit portion of the wireless tag circuit element. And this determination means determines whether the identification command signal containing the individual identification information intrinsic | native to the interrogator was received from the interrogator. Thereby, the interrogator can be specified for each individual on the wireless tag side before and after the inquiry command signal is received from the interrogator. Therefore, it is possible to change the mode of response to the inquiry command signal for each interrogator according to the specified result. As a result, no response is made to a specific interrogator, or the contents of the response signal can be limited, so that security can be improved.

  According to a second invention, in the first invention, the IC circuit unit includes response control means for changing a response mode with respect to the inquiry command signal according to the individual identification information included in the identification command signal. Features.

  By changing the mode of response to the inquiry command signal according to the individual identification information, it is possible not to respond to a specific interrogator or to limit the content of the response signal. Therefore, security can be improved.

  A third invention is characterized in that, in the second invention, the response control means switches between performing and not responding to the interrogator according to the individual identification information.

  Thereby, it is possible to improve security by not responding to a specific interrogator.

  According to a fourth invention, in the second invention, the response control means switches contents of information included in a response signal to the interrogator according to the individual identification information.

  As a result, it is possible to reduce the information included in the response signal for the specific interrogator, to make the information less important, to use only the tag identification information, and to improve the security.

  According to a fifth invention, in the second invention, the response control means switches whether or not the information stored in the IC circuit section can be rewritten according to the individual identification information.

  Thereby, rewriting of the information stored in the wireless tag can be prohibited for a specific interrogator, and security can be improved.

  In a sixth aspect based on the second aspect, the IC circuit section includes first tag identification information related to the RFID circuit element, and second tag identification information different from the first tag identification information. The response control means switches whether to include the first tag identification information or the second tag identification information in a response signal to the interrogator according to the individual identification information. .

  As a result, a response signal including main identification information can be returned to a certain interrogator, while a response signal including sub identification information can be returned to another interrogator. Security can be improved by using different identification information.

  In order to achieve the above object, the seventh aspect of the invention relates to a question for transmitting and receiving information by wireless communication between an IC circuit unit for storing information and a RFID circuit element having a tag side antenna for transmitting and receiving information. An interrogator having an interrogator antenna, an inquiry command signal generating means for generating an inquiry command signal for obtaining information from the IC circuit part of the RFID circuit element, and individual identification information unique to the interrogator An identification command signal generating means for generating an identification command signal including: an inquiry command signal is transmitted to the RFID circuit element via the interrogator-side antenna at a first timing; Transmission control means for transmitting the identification command signal to the RFID circuit element through the interrogator antenna at two timings. It is characterized in.

  In the interrogator of the seventh invention of this application, the identification command signal generation means generates an identification command signal including the individual identification information of the interrogator, and the transmission control means transmits the identification command signal to the wireless tag at the second timing. As a result, the wireless tag can receive the identification command signal, specify the interrogator for each individual, and change the mode of response to the inquiry command signal for each interrogator. As a result, no response is made to a specific interrogator, or the contents of the response signal can be limited, so that security can be improved.

  In order to achieve the above object, an eighth invention is a wireless tag comprising a plurality of interrogators provided in the vicinity of an entrance to a management area, an IC circuit unit for storing information, and a tag side antenna for transmitting and receiving information. A management system including a plurality of wireless tags that are detection targets of the plurality of interrogators, wherein the interrogator transmits and receives information to and from the wireless tag circuit elements by wireless communication. An inquiry command signal generating means for generating an inquiry command signal for acquiring information from the IC circuit unit of the RFID tag circuit element, and an identification command signal including individual identification information unique to the interrogator An identification command signal generating means for generating, and transmitting the inquiry command signal to the RFID circuit element via the interrogator-side antenna at a first timing; Transmission control means for transmitting the identification command signal to the RFID circuit element via the interrogator-side antenna at any second timing before and after imming, and the IC circuit portion of the RFID tag Determination means for determining whether the inquiry command signal from the interrogator is received by the tag-side antenna at one timing and whether the identification command signal from the interrogator is received by the tag-side antenna at the second timing It is characterized by providing.

  In the management system of the eighth invention of the present application, an identification command signal including individual identification information of the interrogator is generated by the identification command signal generation means provided for each of the plurality of interrogators, and the identification command signal is wirelessly tagged by the transmission control means Send to. At this time, the IC circuit portion of the RFID tag circuit element of the RFID tag is provided with a judging means for judging whether or not the identification command signal is received from the interrogator. Thereby, the interrogator can be specified for each individual on the wireless tag side before and after the inquiry command signal is received from the interrogator. Therefore, when the inquiry command signal is transmitted by each of the plurality of interrogators provided in the vicinity of the entrance / exit of the management area to perform the entrance / exit management, each wireless tag passing through the entrance / exit is a mode of response to the inquiry command signal for each interrogator. Can be changed. That is, it is possible to respond only to a specific interrogator corresponding to itself and not to respond to other interrogators, or to limit the contents of the response signal. By doing so, it is possible to keep a record of passage through the entrance / exit only for a specific interrogator corresponding to each wireless tag, and to keep a record of passage through the entrance / exit other than that, so security is improved. Can be improved.

  According to the present invention, security can be improved by identifying an interrogator and changing a response mode.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram schematically showing an overall configuration of a wireless tag management system 1 (management system) of the present embodiment. In this example, the case where the present invention is applied to a multi-purpose building (management area) 2 having a plurality of floors is conceptually shown.

  The multi-use building 2 is used for each floor by a plurality of companies (here, three companies, A company, B company, and C company). And, for example, a person 6 such as a regular employee and contract employee of each company having the residence building 2 as a residence, and a person related to each company and a visitor to each company are set as monitoring targets. Those persons 6 to be monitored carry the wireless tag T.

  The wireless tag management system 1 of the present embodiment has readers (interrogators) 7A to 7C that are installed in the vicinity of the entrance door 3 in the multi-purpose building 2 and are owned by each company in the multi-purpose building 2. is doing. These readers 7 </ b> A to 7 </ b> C make a predetermined question to the RFID tag T possessed by the person 6 when the person 6 to be monitored passes the entrance door 3, and read the response from the RFID tag T , Information on exit / entrance passage and the like is managed (details will be described later). Hereinafter, the readers 7A to 7C will be collectively referred to simply as “reader 7” as appropriate.

  FIG. 2 is a system configuration diagram illustrating an outline of the wireless tag management system 1 of the present embodiment. In FIG. 2, the wireless tag management system 1 has the readers 7 </ b> A to 7 </ b> C that exchange signals with each wireless tag T by wireless communication.

  Each reader 7 includes a control unit 11 and an antenna unit 12 (interrogator-side antenna). The control unit 11 includes a CPU (Central Processing Unit) 13 that performs signal processing in accordance with a program stored in advance in the ROM while using a temporary storage function of the RAM, a memory 15 including, for example, a RAM and a ROM, and the antenna unit 12. And an RF communication control unit 16 that controls wireless communication with the wireless tag T.

  Further, the RFID tag T possessed by the person 6 to be monitored is commonly provided with the RFID circuit element To. The RFID circuit element To is connected to the antenna unit 12 of the reader 7 and an antenna 151 (tag-side antenna) that transmits and receives signals in a non-contact manner using a high frequency such as a UHF band and a microwave band, and the antenna 151. IC circuit unit 150.

  FIG. 3 is a block diagram illustrating an example of a functional configuration of the RFID circuit element To. In FIG. 3, the RFID circuit element To includes the antenna 151 and the IC circuit unit 150.

  The IC circuit unit 150 includes a rectification unit 152 that rectifies the interrogation wave received by the antenna 151 that is the tag side antenna, and a power supply unit that accumulates the energy of the interrogation wave rectified by the rectification unit 152 and uses it as a drive power source. 153, a clock extraction unit 154 that extracts a clock signal from the interrogation wave received by the antenna 151 and supplies the clock signal to a control unit (described later) 157, a memory unit 155 that can store a predetermined information signal, and the antenna 151 And a control unit 157 for controlling the operation of the RFID circuit element To through the memory unit 155, the clock extraction unit 154, the modulation / demodulation unit 156, and the like.

  The modem unit 156 demodulates the communication signal received from the reader antenna of the reader 7 received by the antenna 151 and modulates the interrogation wave received by the antenna 151 based on the return signal from the control unit 157. From 151, it retransmits as a response wave.

  The control unit 157 interprets the received signal demodulated by the modulation / demodulation unit 156, generates a return signal based on the information signal stored in the memory unit 155, and performs basic control such as returning by the modulation / demodulation unit 156. Execute proper control.

  The clock extraction unit 154 extracts a clock component from the received signal and extracts the clock to the control unit 157, and supplies a clock corresponding to the speed of the clock component of the received signal to the control unit 157.

  FIG. 4 is a functional block diagram showing detailed configurations of the CPU 13, the RF communication control unit 16, and the antenna unit 12 in the reader 7.

  In FIG. 4, the RF communication control unit 16 of the reader 7 accesses the information (RFID tag information including the tag ID) of the IC circuit unit 150 of the RFID circuit element To via the antenna unit 12. The CPU 13 of the reader 7 processes a signal read from the IC circuit unit 150 of the RFID circuit element To and reads information, and generates access information for accessing the IC circuit unit 150 of the RFID circuit element To. It includes functions and controls the operation of the entire reader 7.

  The RF communication control unit 16 transmits a signal to the RFID circuit element To via the antenna unit 12, and a reception unit that inputs a reflected wave from the RFID circuit element To received by the antenna unit 12. 213 and a transmission / reception separator 214.

  The transmission unit 212 transmits a signal having a predetermined frequency under the control of the crystal resonator 215A that generates a carrier wave for accessing (reading / writing) the RFID tag information of the IC circuit unit 150 of the RFID circuit element To and the CPU 13. A generated PLL (Phase Locked Loop) 215B, a VCO (Voltage Controlled Oscillator) 215C, and the generated carrier wave are modulated based on a signal supplied from the CPU 13 (in this example, a “TX_ASK” signal from the CPU 13 is converted into a “TX_ASK” signal). A transmission multiplication circuit 216 (amplitude modulation based on this) (however, in the case of “TX_ASK signal”, an amplification factor variable amplifier or the like may be used), and a modulated wave modulated by the transmission multiplication circuit 216 is amplified (in this example, from the CPU 13). The variable transmission amplifier 21 which amplifies the amplification factor by the “TX_PWR” signal It is equipped with a door. The generated carrier wave uses, for example, a frequency in the UHF band or the microwave band, and the output of the transmission amplifier 217 is transmitted to the antenna unit 12 via the transmission / reception separator 214 to be transmitted to the RFID circuit element To. It is supplied to the IC circuit unit 150. Note that the RFID tag information is not limited to the signal modulated as described above, but may be only a carrier wave.

  The receiving unit 213 multiplies the reflected wave from the RFID circuit element To received by the antenna unit 12 by the generated carrier wave and demodulates the received first multiplication circuit 218, and the first receiving multiplication circuit 218. A first band-pass filter 219 for extracting only a signal of a necessary band from the output of the first, a reception first amplifier 221 that amplifies the output of the first band-pass filter 219, and an output of the reception first amplifier 221 A first limiter 220 that amplifies and converts the signal into a digital signal; a reflected wave received from the RFID tag circuit element To received by the antenna unit 12; a carrier wave delayed by 90 ° by the phase shifter 227 after being generated; And a second band for extracting only a signal of a necessary band from the output of the reception second multiplication circuit 222. A pass filter 223; a reception second amplifier 225 that amplifies the output of the second band pass filter 223; and a second limiter 224 that further amplifies the output of the reception second amplifier 225 and converts it into a digital signal. Yes. The signal “RXS-I” output from the first limiter 220 and the signal “RXS-Q” output from the second limiter 224 are input to the CPU 13 for processing.

  The outputs of the reception first amplifier 221 and the reception second amplifier 225 are also input to an RSSI (Received Signal Strength Indicator) circuit 226 as intensity detection means, and a signal “RSSI” indicating the intensity of these signals is input to the CPU 13. It is designed to be entered. In this manner, the reader 7 of this embodiment demodulates the reflected wave from the RFID circuit element To by IQ orthogonal demodulation.

  As described above, the most significant feature of the present embodiment is that whether or not the wireless tag T has received an identification command signal including individual identification information unique to the reader 7 before and after receiving the inquiry command signal from the reader 7, That is, the mode of response to the inquiry command signal is changed according to the identification information. Hereinafter, the details will be described in order.

  FIGS. 5A to 5C are diagrams conceptually showing an example of a response mode table stored and held in the memory unit 155 of the IC circuit unit 150 of the RFID circuit element To. 5A to 5C, each response mode table includes individual identification information (reader ID) of the reader 7 and an inquiry command signal from the reader 7 (a tag ID read command, which will be described later, etc.). ) Is stored in the form of correlation information associated with the presence or absence of a response. Each response mode table is different for each wireless tag T so that a response is made only when an identification command signal is received, including the reader ID of the company (in-house) to which the person 6 who owns the wireless tag T belongs. .

  Specifically, the wireless tag T possessed by the person 6 belonging to the company A is, as shown in FIG. 5A, the reader ID of the company A (in this example, conceptually represented by “ID0001”. The same applies hereinafter. Only when an identification command signal including) is received, a response to the inquiry command signal from the reader is made. As shown in FIG. 5B, the wireless tag T possessed by the person 6 belonging to the company B receives the identification command signal including the reader ID of the company B (in this example, conceptually represented by “ID0002”). It is set to respond to the inquiry command signal only when As shown in FIG. 5C, the wireless tag T possessed by the person 6 belonging to the company C receives the identification command signal including the reader ID of the company C (conceptually represented by “ID0003” in this example). It is set to respond to the inquiry command signal only when

  FIG. 6 is a flowchart showing a control procedure executed by the control unit 157 provided in the IC circuit unit 150 of the RFID circuit element To and the CPU 13 provided in the control unit 11 of the reader 7.

  In FIG. 6, the CPU 13 of the reader 7 first transmits an identification command signal (reader ID notification command signal) including the reader ID unique to each reader via the RF communication control unit 16 and the antenna unit 12 in step S5. Sent to T.

  Correspondingly, the control unit 157 of the RFID circuit element To receives a signal from the reader 7 via the antenna 151 and the modulation / demodulation unit 156 (second timing), and in step S105, the received signal is transmitted to the reader. It is determined whether it is an ID notification command signal. When the reader ID notification command signal has not been received, the determination in step S105 is not satisfied, and this flow by the control unit 157 ends. On the other hand, if the received signal is a reader ID notification command signal, the determination at step S105 is satisfied, and the routine goes to step S107. In step S107, with reference to the response mode table (see FIGS. 5A to 5C) stored and held in the memory unit 155 using the received reader ID as a key, the corresponding reader should respond. (= In other words, whether the reader ID included in the received reader ID notification command signal corresponds to the company) is acquired. Then, it moves to step S110. In step S110, based on the information acquired in step S107, it is determined whether the reader 7 is to respond. If it is not the reader 7 that should make a response (= the reader 7 corresponding to another company), the determination in step S110 is not satisfied, and no response is made to the reader 7, and this flow ends. . If it is the reader 7 that should make a response (= the reader 7 corresponding to the company), the determination in step S110 is satisfied, and the routine goes to step S115 described later.

  On the other hand, the CPU 13 of the reader 7 proceeds to step S10 after a predetermined time has elapsed from step S5. In this step S10, a tag ID read command signal which is an inquiry command signal is transmitted to the wireless tag T via the RF communication control unit 16 and the antenna unit 12, and an individual unique to the wireless tag circuit element To of the wireless tag T is transmitted. The user is prompted to return a tag ID that is identification information.

  Correspondingly, the control unit 157 of the RFID circuit element To receives the tag ID read command signal from the reader 7 via the antenna 151 and the modem unit 156 when the determination in step S110 is satisfied. (First timing). Thereafter, in step S115, a response signal including the tag ID (including other public data if necessary) is transmitted to the reader 7 that has received the tag ID read command signal via the modem unit 156 and the antenna 151, End the flow.

  In response to this, the CPU 13 of the reader 7 receives the response signal from the control unit 157 via the antenna unit 12 and the RF communication control unit 16, and then in step S14, outputs the tag ID read command signal in step S10. It is determined whether the tag ID has been replied since the transmission or whether a predetermined time has elapsed. Until the tag ID is responded or until a predetermined time elapses, the determination in step S14 is not satisfied, and the reception of the response signal from the control unit 157 of the RFID circuit element To is continued. If the tag ID is responded or if a predetermined time elapses and a time-out occurs, the determination in step S14 is satisfied and the flow ends.

  Note that the processing of steps S5 to S15 by the CPU 13 is repeatedly executed at a predetermined cycle as long as the reader 7 is powered on.

  Further, the process of transmitting the tag ID read command signal in step S10 may be performed before the process of transmitting the reader ID notification command signal in step S5. In this case, when the determination in step S110 by the control unit 157 of the RFID circuit element To is satisfied, a process of responding to the reader 7 in step S115 is executed (without receiving a signal from the reader 7). This is enough.

  In the above, step S105 in the flow of FIG. 6 is the individual identification specific to the interrogator 7 at the second timing before or after the first timing when the inquiry command signal from the interrogator 7 is received by the tag side antenna 151. The determination means which determines whether the identification command signal containing information was received by the tag side antenna 151 is comprised. Step S110 constitutes response control means for changing the response mode to the inquiry command signal in accordance with the individual identification information included in the identification command signal.

  The step S10 constitutes inquiry command signal generation means for generating an inquiry command signal for obtaining information from the IC circuit unit 150 of the RFID circuit element To. Step S5 constitutes an identification command signal generating means for generating an identification command signal including individual identification information unique to the interrogator 7. These steps S5 and S10 as a whole transmit an inquiry command signal to the RFID circuit element To via the interrogator antenna 12 at the first timing, and at the second timing either before or after the first timing. The transmission control means is configured to transmit the identification command signal to the RFID circuit element To via the.

  As described above, in this embodiment, the reader 7 installed in the vicinity of the entrance door 3 of the multi-purpose building 2 sequentially transmits the reader ID notification command signal and the tag ID read command signal at different timings. At this time, the IC circuit unit 150 of the RFID tag circuit element To of the RFID tag T possessed by the person 6 who entered the occupancy building 2 from the entrance door 3 has received the reader ID notification command signal from the reader 7. Determine whether or not. Thereby, before and after receiving the tag ID read command signal from the reader 7, the reader 7 can be identified individually on the RFID circuit element To side. Then, a response is made only to the reader 7 of the company corresponding to its own RFID circuit element To, and no response is made to the reader 7 of another company. Accordingly, it is possible to keep the entry / exit passage record only in the reader 7 of the company corresponding to each wireless tag T, and to prevent the other readers 7 from recording the entrance / exit passage. As a result, the security at the time of entering / exiting management of the multi-use building 2 can be improved.

  In addition, this embodiment is not restricted above, A various deformation | transformation is possible in the range which does not deviate from the meaning and technical idea. Hereinafter, such modifications will be described in order.

(1) When changing the content of the response information to the reader 7 according to the reader ID In the above embodiment, whether to respond to the reader 7 or not to be performed is switched according to the reader ID of the reader 7. However, the present invention is not limited to this. For example, the content of information included in the response signal to the reader 7 may be changed according to the reader ID of the reader 7.

  FIG. 7 conceptually shows a response mode table stored and held in the memory unit 155 of the IC circuit unit 150 of the RFID circuit element To in such a modification. It is a corresponding figure. Similarly to FIGS. 5A to 5C, the response mode table also includes the reader ID of the reader 7 and the inquiry command signal from the reader 7 (a tag ID read command, public data described later) for each wireless tag T. Read command, secret data read command, etc.) and the corresponding response level are stored in the form of correlation information.

The response level includes the following levels 0 to 4. The response level is set so that, for example, the reader 7 of the company having a high degree of association with the person 6 who possesses the wireless tag T becomes higher. For the reader 7 whose reader ID is not registered in the wireless tag T, the response level is level 0.
Level 0: No response.
Level 1: Only the tag ID is included in the response signal. Rewriting is not permitted.
Level 2: The response signal includes the tag ID and public data. Rewriting is not allowed.
Level 3: The response signal includes tag ID, public data, and secret data.
Public data can be rewritten, but confidential data cannot be rewritten.
Level 4: Tag ID, public data, and secret data are included in the response signal.
Public data rewrite is permitted, but confidential data is not rewritten.
Rewrite permission of reader ID of level X (X is any one of 1-4).

  The public data (including rewritable / prohibited information) and secret data are stored in advance as map data in the memory unit 155 of the IC circuit unit 150 together with the tag ID (see also FIG. 12 described later).

  FIG. 8 shows that in this modification, the control unit 157 provided in the IC circuit unit 150 of the RFID circuit element To and the CPU 13 of the reader 7 corresponding to the level 1 for the RFID circuit element To are executed. It is a flowchart showing a control procedure. FIG. 8 is a diagram corresponding to FIG. 6 described above, and the same steps as those in FIG. 6 are denoted by the same reference numerals.

  In FIG. 8, the CPU 13 of the reader 7 first performs step S5 similar to that in FIG. 6, and the control unit 157 of the RFID circuit element To correspondingly performs step S105 similar to FIG. When the reader ID notification command signal is received and the determination in step S105 is satisfied, the process proceeds to step S107, which is the same as in FIG. 6, and what kind of response is made to the corresponding reader with reference to the response mode table. Get information about. Thereafter, the process proceeds to newly provided step S125.

  On the other hand, the CPU 13 of the reader 7 transmits a tag ID read command signal, which is an inquiry command signal, in step S10 after a predetermined time has elapsed from step S5, as in FIG.

  Correspondingly, the control unit 157 of the RFID circuit element To receives the tag ID read command signal from the reader 7 via the antenna 151 and the modem unit 156 after the step S107 (first timing). . After that, in step S125, as in step S115 described above, a response signal including the tag ID is transmitted to the reader 7 that has received the tag ID read command signal via the modem unit 156 and the antenna 151.

  Correspondingly, the CPU 13 of the reader 7 receives the response signal from the control unit 157 via the antenna unit 12 and the RF communication control unit 16, and then in step S20 newly provided, as in step S5, the reader ID An identification command signal (reader ID notification command signal) is transmitted.

  In response to this, the control unit 157 of the RFID circuit element To receives a signal from the reader 7 via the antenna 151 and the modulation / demodulation unit 156 (second timing), and similarly to step S105, a newly provided step S130 is provided. In step (1), it is determined whether the received signal is the reader ID notification command signal. When the reader ID notification command signal is not received, the determination in step S130 is not satisfied, and the flow by the control unit 157 is terminated. On the other hand, if the received signal is a reader ID notification command signal, the determination in step S130 is satisfied, and the process proceeds to newly provided step S135. In step S135, as in step S107, the response mode table is referenced using the received reader ID as a key, and information on what kind of response is made to the corresponding reader is acquired.

  On the other hand, the CPU 13 of the reader 7 proceeds to step S25 after a predetermined time has elapsed from step S20. In step S25, a public data read command signal, which is an inquiry command signal, is transmitted to the wireless tag circuit element To corresponding to the tag ID of the received response signal via the RF communication control unit 16 and the antenna unit 12. A reply response of the public data from the tag T is prompted (first timing). However, since the reader 7 corresponds to level 1 (only the tag ID responds) for the RFID circuit element To, the RFID circuit element To does not respond to the public data read command signal (or reads the public data). May be made to respond, that is, a response is made with the information “response rejected”, or a response may be made with information on dummy contents set in advance).

  In this state, the CPU 13 of the reader 7 determines in step S15 whether or not a predetermined time has elapsed since the public data read command signal was transmitted in step S25. When a predetermined time elapses after the transmission of the public data read command signal, the determination in step S15 is satisfied and a time-out occurs, and this flow ends without receiving the public data response from the RFID circuit element To.

  FIG. 9 shows that in this modification, the control unit 157 provided in the IC circuit unit 150 of the RFID circuit element To and the CPU 13 of the reader 7 corresponding to the level 2 for the RFID circuit element To are executed. It is a flowchart showing a control procedure. Steps equivalent to those in FIGS. 6 and 8 are given the same reference numerals.

  9, step S5, step S105, step S107, step S10, step S125, step S10, step S125, step S20, step S130, step are executed by the CPU 13 of the reader 7 and the control unit 157 of the RFID circuit element To. Steps S135 and S25 are the same as in FIG.

  As described above, after the CPU 13 of the reader 7 transmits the public data read command signal in step S25, the reader 7 corresponds to level 2 (response to the tag ID and the public data) in the example of FIG. For this reason, the RFID circuit element To receives the response signal including the public data from the modulation / demodulation unit 156 and the antenna 151 in Step S140, as in Steps S115 and S125. Transmit to the reader 7.

  Correspondingly, the CPU 13 of the reader 7 receives the response signal from the control unit 157 via the antenna unit 12 and the RF communication control unit 16, and then in step S30 newly provided, similar to step S20 and step S5. The identification command signal (reader ID notification command signal) including the reader ID is transmitted.

  Correspondingly, the control unit 157 of the RFID circuit element To receives a signal from the reader 7 via the antenna 151 and the modulation / demodulation unit 156 (second timing), and newly performs the same as in Step S105 and Step S130. In the provided step S145, it is determined whether or not the received signal is the reader ID notification command signal. When the reader ID notification command signal has not been received, the determination in step S145 is not satisfied, and this flow by the control unit 157 ends. On the other hand, if the received signal is a reader ID notification command signal, the determination in step S145 is satisfied, and the flow proceeds to newly provided step S150. In step S150, as in step S135 and step S107, the response mode table is referenced using the received reader ID as a key, and information on what response is made to the corresponding reader is acquired.

  On the other hand, the CPU 13 of the reader 7 proceeds to step S35 after a predetermined time has elapsed from step S30. In step S35, the confidential data read command signal, which is an inquiry command signal, is transmitted to the wireless tag circuit element To corresponding to the tag ID of the received response signal via the RF communication control unit 16 and the antenna unit 12, and wirelessly transmitted. A response response of secret data from the tag T is prompted (first timing). However, since the reader 7 corresponds to level 2 (only the tag ID and public data respond) for the RFID circuit element To, the RFID circuit element To does not respond to the secret data read command signal (or A response may be made to reject the reading of the confidential data, that is, a response is made with the information “response rejected”, or a response may be made with information about dummy contents set in advance).

  In this state, the CPU 13 of the reader 7 determines in step S15 whether or not a predetermined time has elapsed since the transmission of the secret data read command signal in step S35, as in FIG. When a predetermined time has elapsed since the transmission of the secret data read command signal, the determination in step S15 is satisfied and a time-out occurs, and this flow ends without receiving a response to the public data from the RFID circuit element To.

  FIG. 10 shows that in this modification, the control unit 157 provided in the IC circuit unit 150 of the RFID circuit element To and the CPU 13 of the reader 7 corresponding to the level 3 for the RFID circuit element To execute. It is a flowchart showing a control procedure. The same steps as those in FIGS. 6, 8, 9 and the like are denoted by the same reference numerals.

  10, step S5, step S105, step S107, step S10, step S125, step S30, step S145, step S150, and step S35 are executed by the CPU 13 of the reader 7 and the control unit 157 of the RFID circuit element To. Since it is the same as FIG. 9, description is abbreviate | omitted. In FIG. 10, step S20, step S130, step S135, step S25, and step S140 in FIG. 9 are omitted, but may be performed in the same manner as in FIG.

  As described above, after the CPU 13 of the reader 7 transmits the secret data read command signal in step S35, the reader 7 corresponds to level 3 (tag ID, public data, response to concealment) in the example of FIG. For this reason, the RFID circuit element To sends a response signal including confidential data to the confidential data read command signal via the modem 156 and the antenna 151 in step S155, as in steps S115, S125, and S140. The data is transmitted to the received reader 7.

  In response to this, the CPU 13 of the reader 7 receives the response signal from the control unit 157 via the antenna unit 12 and the RF communication control unit 16, and then in step S40 newly provided, step S30, step S20, As in step S5, an identification command signal (reader ID notification command signal) including the reader ID is transmitted.

  Correspondingly, the control unit 157 of the RFID circuit element To receives a signal from the reader 7 via the antenna 151 and the modulation / demodulation unit 156 (second timing), and is similar to step S105, step S130, or step S145. In step S160 newly provided, it is determined whether or not the received signal is the reader ID notification command signal. When the reader ID notification command signal has not been received, the determination in step S160 is not satisfied, and this flow by the control unit 157 ends. On the other hand, if the received signal is a reader ID notification command signal, the determination in step S160 is satisfied, and the flow proceeds to newly provided step S165. In step S165, as in step S150, step S135, or step S107, the response mode table is referenced using the received reader ID as a key, and information on what response is made to the corresponding reader is acquired. To do.

  On the other hand, the CPU 13 of the reader 7 proceeds to step S45 after a predetermined time has elapsed from step S40. In step S45, a public data write command signal, which is an inquiry command signal, is transmitted to the wireless tag circuit element To corresponding to the tag ID of the received response signal via the RF communication control unit 16 and the antenna unit 12. The public data stored in the IC circuit unit 150 of the RFID tag circuit element To of the tag T is written (the data may be written after inquiring whether it can be rewritten).

  In response to this, the RFID circuit element To writes public data corresponding to the above in step S170, and then proceeds to step S175, and in the same manner as in step S140, the predetermined response after writing. A response signal including (for example, a rewrite success identifier) is transmitted to the reader 7 that has received the public data write command signal via the modem unit 156 and the antenna 151.

  Correspondingly, the CPU 13 of the reader 7 receives the response signal from the control unit 157 via the antenna unit 12 and the RF communication control unit 16, and then in step S50 newly provided, as in step S30 and the like. An identification command signal (reader ID notification command signal) including the reader ID is transmitted.

  Correspondingly, the control unit 157 of the RFID circuit element To receives a signal from the reader 7 via the antenna 151 and the modulation / demodulation unit 156 (second timing), and is newly provided as in step S160 and the like. In step S180, it is determined whether the received signal is the reader ID notification command signal. When the reader ID notification command signal has not been received, the determination in step S180 is not satisfied, and this flow by the control unit 157 ends. On the other hand, if the received signal is a reader ID notification command signal, the determination in step S180 is satisfied, and the flow proceeds to newly provided step S185. In step S185, as in step S165 and the like, the response mode table is referenced using the received reader ID as a key, and information on what response is made to the corresponding reader is acquired.

  On the other hand, the CPU 13 of the reader 7 proceeds to step S55 after a predetermined time has elapsed from step S50. In step S55, the RFID tag circuit element To corresponding to the tag ID of the response signal received via the RF communication control unit 16 and the antenna unit 12 is sent to the response mode table (in this example, the level of the inquiry command signal). 4) (reader ID rewrite command signal) is transmitted, an attempt is made to rewrite the response mode table stored in the IC circuit unit 150 of the RFID tag circuit element To of the RFID tag T. Data may be written). However, since the reader 7 corresponds to level 3 (reader ID rewriting is not permitted) for the RFID circuit element To, the RFID circuit element To does not respond to the reader ID rewrite command signal (or A response to reject the reader ID rewrite may be made, that is, a response is made with the information “response rejected”, or a response may be made with information on dummy contents set in advance).

  In this state, the CPU 13 of the reader 7 determines in step S15 whether or not a predetermined time has elapsed since the reader ID rewrite command signal was transmitted in step S55 in the same manner as described above. When a predetermined time elapses after the reader ID rewrite command signal is transmitted, the determination in step S15 is satisfied and a time-out occurs, and this flow ends without receiving a response from the RFID circuit element To.

  In this modified example as described above, it is determined whether the RFID circuit element To has received the reader ID notification command signal from the reader 7, and the content of the response signal to the reader 7 is limited according to the reader ID ( Since the information quality is limited to public information that is less important, or only the tag ID, etc. (or the information may be reduced), the security when managing the entrance / exit of the multi-purpose building 2 is improved. Can do. In addition, since rewriting of public data is prohibited for a specific reader 7, it can contribute to further improvement of security.

(2) In the case where two tag IDs are provided for one RFID tag T In the above embodiment and the modification of (1), one RFID circuit element To is provided with one tag ID. The present invention is not limited to this. That is, one RFID circuit element To may be provided with a main tag ID and a sub tag ID, and these tag IDs may be used properly according to the reader ID of the reader 7.

  FIG. 11 is a flowchart showing a control procedure executed by the CPU 13 of the reader 7 and the control unit 157 of the IC circuit unit 150 of the RFID circuit element To in this modification. The same steps as those in FIG. 6 described above are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

  11, step S5, step S105, step S107, step S110, step S10, and step S14 executed by the CPU 13 of the reader 7 and the control unit 157 of the RFID circuit element To are the same as those in FIG. Is omitted.

  However, in this modification, in step S110, if the determination is not satisfied instead of the reader 7 to which a response is to be made, the process proceeds to step S115B. If the determination is satisfied because the reader 7 is to perform the response, the process proceeds to step S115A. Move.

  That is, in step S115A, the control unit 157 of the RFID circuit element To transmits a main tag ID (first tag identification information) as a response signal to the reader 7 that has received the tag ID read command signal. Exit. On the other hand, in step S115B, the sub tag ID (second tag identification information) is transmitted as a response signal to the reader 7 that has received the tag ID read command signal, and this flow ends.

  Note that step S110 in FIG. 11 constitutes response control means for switching whether to include the first tag identification information or the second tag identification information in the response signal to the interrogator according to the individual identification information. .

  In this modification, since the main tag ID and the sub tag ID are separately transmitted according to the reader ID as described above, the security at the time of entrance / exit management of the occupancy building 2 is further improved. be able to. The control unit 157 of the RFID circuit element To is not limited to using the sub tag ID. In other words, the control unit 157 may respond using information on dummy contents newly set apart from the tag ID. In this case, the same effect is obtained.

(3) When storing the response level for the reader 7 together with the tag ID and data In the modification of the above (1), the response level for the reader 7 is stored and held as a table in association with the reader ID. Not limited to. That is, it may be stored and held as a memory map together with the tag ID, public data, secret data, and the like.

  FIG. 12 is a diagram conceptually illustrating an example of the above-described memory map stored in the memory unit 155 of the IC circuit unit 150.

  In FIG. 12, the data portion of the memory map includes a tag ID of the wireless tag T, an application code, public data (including rewritable / prohibited information), confidential data, and a reader corresponding to the above response level (excluding level 0). ID is registered in advance.

  Even when such a memory map is adopted, control procedures executed by the CPU 13 of the reader 7 and the control unit 157 of the IC circuit unit 150 of the wireless tag T are the same as those shown in FIGS. Can get the same effect.

(4) Others In addition to those described above, the methods according to the above-described embodiments and modifications may be used in appropriate combination.

  In addition, although not illustrated one by one, the present invention is implemented with various modifications within a range not departing from the gist thereof.

1 is a diagram schematically showing an overall configuration of a wireless tag management system according to an embodiment of the present invention. 1 is a system configuration diagram illustrating an outline of a wireless tag management system. It is a block diagram showing an example of a functional structure of the RFID circuit element with which the RFID tag was equipped. It is a functional block diagram showing the detailed structure of the RF communication control part and reader antenna in a reader. It is a figure which represents an example of a response mode table notionally. It is a flowchart showing the control procedure regarding the monitoring operation | movement which CPU of the control part of a reader | leader and the control part of the IC circuit part of a RFID circuit element perform. It is a figure which represents notionally another example of a response mode table. It is a flowchart showing the modification of the control procedure regarding the monitoring operation | movement which CPU of the control part of a reader | leader and the control part of the IC circuit part of a RFID circuit element perform. It is a flowchart showing the modification of the control procedure regarding the monitoring operation | movement which CPU of the control part of a reader | leader and the control part of the IC circuit part of a RFID circuit element perform. It is a flowchart showing the modification of the control procedure regarding the monitoring operation | movement which CPU of the control part of a reader | leader and the control part of the IC circuit part of a RFID circuit element perform. 10 is a flowchart illustrating another modification of the control procedure related to the monitoring operation performed by the CPU of the reader control unit and the control unit of the IC circuit unit of the RFID circuit element. It is a figure showing an example of a memory map notionally.

Explanation of symbols

1 RFID tag management system 2 Miscellaneous building (managed area)
3 Entrance door 7 Leader (interrogator)
7A-7C reader (interrogator)
11 Control unit 12 Reader antenna (interrogator side antenna)
13 CPU
16 RF communication control unit 150 IC circuit unit 151 Antenna (tag side antenna)
157 Control unit T wireless tag To wireless tag circuit element

Claims (8)

A wireless tag circuit element having an IC circuit unit for storing information and a tag side antenna for transmitting and receiving information;
The IC circuit unit is
An identification command signal including individual identification information unique to the interrogator is received by the tag side antenna at a second timing before or after the first timing at which the inquiry command signal from the interrogator is received by the tag side antenna. A wireless tag comprising: determination means for determining whether or not The wireless tag according to claim 1, wherein
The IC circuit unit is
A wireless tag comprising: response control means for changing a mode of a response to the inquiry command signal according to the individual identification information included in the identification command signal. The wireless tag according to claim 2, wherein
The response control means includes
A wireless tag, which switches between performing and not responding to the interrogator according to the individual identification information. The wireless tag according to claim 2, wherein
The response control means includes
A wireless tag, wherein the content of information included in a response signal to the interrogator is switched according to the individual identification information. The wireless tag according to claim 2, wherein
The response control means includes
A wireless tag that switches whether information stored in the IC circuit unit can be rewritten according to the individual identification information. The wireless tag according to claim 2, wherein
The IC circuit unit is
First tag identification information related to the RFID circuit element, and second tag identification information different from the first tag identification information,
The response control means includes
A wireless tag that switches between including the first tag identification information or the second tag identification information in a response signal to the interrogator according to the individual identification information. An interrogator having an interrogator-side antenna for transmitting and receiving information by wireless communication between an IC circuit unit for storing information and a RFID tag circuit element having a tag-side antenna for transmitting and receiving information,
Inquiry command signal generating means for generating an inquiry command signal for acquiring information from the IC circuit unit of the RFID circuit element;
Identification command signal generation means for generating an identification command signal including individual identification information unique to the interrogator,
The inquiry command signal is transmitted to the RFID circuit element via the interrogator-side antenna at a first timing, and the identification command signal is transmitted via the interrogator-side antenna at a second timing before or after the first timing. An interrogator comprising transmission control means for transmitting to the RFID circuit element. A plurality of interrogators near the entrance to the controlled area;
A management system comprising a wireless tag circuit element having an IC circuit unit for storing information and a tag-side antenna for transmitting and receiving information, and having a plurality of wireless tags to be detected by the plurality of interrogators,
The interrogator is
An interrogator-side antenna that transmits and receives information by wireless communication with the wireless tag circuit element;
Inquiry command signal generating means for generating an inquiry command signal for acquiring information from the IC circuit unit of the RFID circuit element;
Identification command signal generation means for generating an identification command signal including individual identification information unique to the interrogator,
The inquiry command signal is transmitted to the RFID circuit element via the interrogator-side antenna at a first timing, and the identification command signal is transmitted via the interrogator-side antenna at a second timing before or after the first timing. Transmission control means for transmitting to the RFID circuit element,
The IC circuit portion of the wireless tag is
It is determined whether the inquiry command signal from the interrogator is received by the tag side antenna at the first timing, and whether the identification command signal from the interrogator is received by the tag side antenna at the second timing. A management system comprising a determination unit.

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