JP2009301374A - Rfid tag system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an RFID (Radio Frequency IDentification) tag system allowing execution of a notification in a notification means such as an LED, a buzzer or the like while suppressing power of an electric wave irradiated on an antenna so as to drive the notification means of an RFID tag. <P>SOLUTION: A reader/writer 21 includes a handy reader/writer 51 and an installed reader/writer 52. The installed reader/writer 52 is disposed near the RFID tag 1 stuck on a spine cover of a book displayed in a bookshelf. When a user searches for a desired book, a peculiar ID designation signal wherein a peculiar ID of the RFID tag 1 to be searched for is designated is transmitted from the handy reader/writer 51, next, an identification ID designation signal is transmitted from the installed reader/writer 52, and the LED 17 of the RFID tag 1 to be searched for is made to be turned on. In the RFID tag 1, based on that the identification ID designation signal is irradiated, power necessary to turn on the LED 17 is generated. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an RFID tag system. More specifically, the present invention relates to an RFID tag system that can efficiently supply power necessary for executing notification by a notification means provided in the RFID tag from a reader / writer.

In recent years, distribution management of articles has been performed by attaching RFID (Radio Frequency IDentification) tags to articles and reading them with a reader / writer. In addition, by adding a notification means such as an LED or a buzzer to the RFID tag and causing the notification means of the specific RFID tag to react with the reader / writer to execute the notification, a desired RFID tag is selected from a plurality of RFID tags. An RFID tag that can be found, an article search system using the RFID tag, and an article storage system have been proposed.
JP 2006-24018 A

  However, the notification means such as LED and buzzer attached to the RFID tag generally consumes a large amount of power. Therefore, in order to generate the driving power of the notification means based on electromagnetic induction by radio wave irradiation to the antenna, it has been a problem that a very strong radio wave must be applied from the outside.

  The present invention has been made in order to solve the above-described problems. In order to drive the informing means included in the RFID tag, the informing means such as an LED or a buzzer is informed while suppressing the power of the radio wave applied to the antenna. An object of the present invention is to provide an RFID tag system capable of executing the above.

  In order to solve the above-described problem, an RFID tag system according to a first aspect of the present invention is an RFID tag system that searches for a desired RFID tag using a reader / writer, and the RFID tag includes an RFID chip and the RFID tag. An antenna connected to the chip, which supplies an electric signal generated when the signal radio wave transmitted from the reader / writer is irradiated to the RFID chip, and uses the electric signal transmitted from the RFID chip as the signal radio wave A first tag antenna that is an antenna to transmit, a second tag antenna that is an antenna different from the first tag antenna, a tag storage unit that stores an identification ID that is an ID for identifying the RFID tag, and a reader Occurs when the signal wave transmitted from the writer is applied to the second tag antenna. Tag receiving means for demodulating and receiving an air signal, tag notifying means for notifying, and tag control for controlling the tag notifying means and executing notification based on the signal demodulated and received by the tag receiving means And tag power supply means for supplying power for driving the tag receiving means, the tag notification means, and the tag control means, and the signal radio wave transmitted from the reader / writer is transmitted to the second tag antenna. Tag power supply means for generating power from an electrical signal generated when irradiated, and the RFID chip has a chip storage means for storing a unique ID which is an ID for identifying the RFID chip; Chip receiving means for demodulating and receiving an electric signal generated by one tag antenna, and transmitting the modulated electric signal to the first tag antenna; Chip transmitting means for transmitting a signal radio wave from an antenna, and the reader / writer stores an identification ID for identifying the RFID tag and a unique ID for identifying the RFID chip in association with each other. A first R / W antenna that transmits and receives a signal radio wave using a frequency that can be transmitted and received by the first tag antenna; and a modulated signal that is transmitted as a signal radio wave from the first R / W antenna. One R / W transmitter, a first R / W receiver for demodulating and receiving an electrical signal generated in the first R / W antenna, and a signal radio wave using a frequency that can be transmitted and received by the second tag antenna An antenna that is disposed at a position where the distance between the RFID tag and the RFID tag is shorter than the distance between the first R / W antenna and the RFID tag. That a second R / W antenna, and a second R / W transmission means for transmitting the modulated signal as the signal wave from the second R / W antenna.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect of the invention, the reader / writer is unique for identifying the RFID chip incorporated in a desired RFID tag. After the unique ID designation signal, which is a signal designating the ID, is modulated, the first R / W transmission means transmits the signal to the RFID tag, and the RFID tag generates electric power generated by the first tag antenna. The signal is demodulated and received by the chip receiving means, the signal demodulated and received by the chip receiving means is a unique ID designation signal, and the unique ID designated by the unique ID designation signal And the unique ID stored in the chip storage means satisfy a predetermined relationship, the chip transmission means modulates and transmits a response signal, and the reader / writer When the response signal returned from the desired RFID tag is demodulated and received by the first R / W reception means in response to the unique ID designation signal transmitted by one R / W transmission means, the response signal is transmitted. The identification ID possessed by the RFID tag is extracted with reference to the R / W storage means, and after the identification ID designation signal, which is a signal designating the extracted identification ID, is modulated, the second R / W transmission means Tag power supply means is transmitted to the RFID tag, and the RFID tag irradiates the second tag antenna with the signal radio wave transmitted by the second R / W transmission means of the reader / writer. However, after generating power for driving the tag receiving means, the tag notifying means, and the tag control means, the tag receiving means demodulates and receives the electric signal generated by the second tag antenna. The signal demodulated and received by the tag receiving means is an identification ID designation signal that is a signal designating an identification ID, and the identification ID and the identification stored in the tag storage means When the ID satisfies a predetermined relationship, the tag control unit controls the tag notification unit to perform notification.

  In the RFID tag system according to the first aspect of the present invention, the RFID tag includes a second tag antenna that generates electric power separately from the first tag antenna for driving the RFID chip. The reader / writer also includes a first R / W antenna for supplying signal radio waves to the first tag antenna and a second R / W antenna for transmitting signal radio waves to the second tag antenna. The second R / W antenna is arranged closer to the RFID tag than the first R / W antenna. Here, the electric power for driving the notification means included in the RFID tag is generated based on the signal radio wave being applied to the second tag antenna, but the second R / W antenna is disposed near the RFID tag. Therefore, even when the output of the signal radio wave transmitted from the second R / W antenna is suppressed, the second tag antenna can receive the signal radio wave with strong power. As described above, it is possible to drive the tag notification means included in the RFID tag while suppressing the transmission power of the signal radio wave from the reader / writer as much as possible.

  In the RFID tag system according to the second aspect of the invention, the reader / writer first transmits a unique ID designating signal designating the unique ID of the RFID chip built in the RFID tag to be searched, so that the desired RFID tag can be obtained. Check if it exists. Then, when a response signal is returned from the desired RFID tag, it is determined that the desired RFID tag is present, and the RFID tag is identified in order to cause the notification means of the RFID tag to perform notification. An identification ID designation signal designating the identification ID is transmitted. Thereby, in addition to the effect of the invention of claim 1, the reader / writer can confirm that the desired RFID tag exists in the radiation range of the radiated radio wave, and then execute notification from the RFID tag. It becomes. The reader / writer only needs to transmit the radio wave irradiated to drive the RFID tag notification unit only when the RFID tag is within the radiation range of the radiated radio wave. There is no need to transmit a driving radio wave, and the power consumption of the reader / writer can be reduced. Furthermore, in this RFID tag system, since the reader / writer can confirm in advance that the desired RFID tag does not exist nearby, the user has the desired RFID tag within the radiation range of the radio wave emitted from the reader / writer. This can be confirmed in advance and the RFID tag can be notified. Therefore, even if a state in which the user has overlooked the RFID tag is generated even though the RFID tag is reporting from the notification means, the user has a desired RFID tag in the vicinity. Therefore, it is possible to reliably search for the RFID tag.

  Embodiments of an RFID tag 1, a reader / writer 21 (a handy reader / writer 51, an installed reader / writer 52), and an RFID tag system 50 embodying the present invention will be described below with reference to the drawings. These drawings are used for explaining the technical features that can be adopted by the present invention, and the configuration of the apparatus described, the flowcharts of various processes, etc., unless otherwise specified. It is not intended to be limited to that, but merely an illustrative example.

  First, an outline of a book search system, which is an example of an RFID tag system 50 using the RFID tag 1 and the reader / writer 21 (the handy reader / writer 51, the installed reader / writer 52), will be described with reference to FIG. FIG. 1 is a schematic diagram showing a book search system.

  As shown in FIG. 1, a plurality of books 100 with the RFID tag 1 attached to the spine are displayed on the bookshelf. The RFID tag 1 is provided with an LED 17. Then, the user uses the handy reader / writer 51 (details will be described later) and the installation reader / writer 52 (details will be described later), and the LED 17 of the RFID tag 1 attached to a desired book among these books. The book is searched by turning it on.

  An outline of the book search method will be described. First, the user inputs information on a book to be searched (title “XXX”, book number, etc., hereinafter referred to as “book related information”) from the input unit 27 of the handy reader / writer 51. Then, the user sets the radiation surface on the handy reader / writer 51 that radiates radio waves (the hand depth side of the handy reader / writer 51 in FIG. 1) to the bookshelf side and starts the search.

  When the search is started, the first R / W antenna 25 (see FIG. 4, which will be described later), which is an antenna attached to the handy reader / writer 51, is attached to the book to be searched (hereinafter referred to as “search book”). A signal radio wave designating the RFID tag 1 (hereinafter referred to as “search RFID tag”) is emitted. In this state, the user sequentially irradiates the displayed books with signal radio waves while gradually changing the direction of the signal radio waves emitted from the handy reader / writer 51. And the signal radio wave is irradiated to the search RFID tag 1 stuck on the spine of the search book among the books displayed on the bookshelf.

  When the handy reader / writer 51 detects that the search RFID tag 1 has been irradiated with signal radio waves, the handy reader / writer 51 then enables communication between the handy reader / writer 51 and the installed reader / writer 52. Therefore, data is transmitted to the installed reader / writer 52 via the communication lines 53 and 54 provided for the purpose. The installed reader / writer 52 is arranged on the back of the bookshelf at a position where it can irradiate signal radio waves to the RFID tag 1 that is attached to the spine of the book. Then, the installation reader / writer 52 that has received the data from the handy reader / writer 51 irradiates the search RFID tag 1 with a signal radio wave from a second R / W antenna 31 (see FIG. 4, which will be described later), which is an attached antenna. .

  The RFID tag 1 irradiated with the signal radio wave from the installed reader / writer 52 determines whether the RFID tag 1 itself is a search RFID tag designated by the handy reader / writer 51 and the installed reader / writer 52 from the demodulated signal radio wave. . If it is determined that the RFID tag is a search RFID tag, the RFID tag 1 turns on the LED 17. The user who has recognized this recognizes a book (title: “XXX”) to which the RFID tag 1 whose LED 17 is lit is attached among the plurality of books as a search book.

  Here, in the RFID tag 1, the electric power necessary for turning on the LED 17 is generated from radio waves radiated from the installation reader / writer 52. Specifically, when the radio wave radiated from the second R / W antenna 31 of the installation reader / writer 52 is irradiated to the loop antenna of the RFID tag 1, the current generated by electromagnetic induction is stored, and the LED 17 is turned on. It is used as electric power (details will be described later).

  Further, as shown in FIG. 1, the installed reader / writer 52 is disposed on the back of the bookcase, so that the distance between the RFID tag 1 and the handy reader / writer 51 used in the state of being held by the user. Is close. The electric power of the radio wave greatly depends on the propagation distance. When the propagation distance is long, the attenuation amount of the power becomes large. However, in the above-described book search system, a large amount of power necessary to turn on the LED 17 is generated from a radiated radio wave from the installed reader / writer 52 disposed at a short distance from the RFID tag 1. As a result, the LED 17 can be turned on while suppressing the power of the radio wave radiated from the reader / writer 21 as much as possible.

  Next, the electrical configuration of the RFID tag 1 and the reader / writer 21 will be described with reference to FIGS. 2 is a schematic diagram showing an electrical configuration of the RFID tag 1, FIG. 3 is a schematic diagram showing a power source configuration of the RFID tag 1, and FIG. 4 shows a reader / writer 21 (a handy reader / writer 51 and an installed reader). It is a schematic diagram which shows the electrical structure of the writer 52).

  First, the electrical configuration of the RFID tag 1 will be described with reference to FIG. As shown in FIG. 2, the RFID tag 1 includes an RFID chip 40, a notification control communication unit 41, a first antenna 5 connected to the RFID chip 40, and a second connection connected to the notification control communication unit 41. And an antenna 15.

  Of these, the first antenna 5 and the second antenna 15 are so-called loop antennas. When a radio wave is irradiated, it is possible to generate a current by electromagnetic induction, and it is possible to radiate a radio wave of a predetermined frequency by transmitting an electric signal to each antenna. .

  The first antenna 5 and the second antenna 15 have their loop diameters and turns adjusted so that a resonance phenomenon occurs at a predetermined frequency. As a result, when a signal radio wave emitted from the reader / writer 21 (the handy reader / writer 51 and the installed reader / writer 52) is irradiated, an electric signal can be efficiently extracted. In addition, when an electric signal is transmitted from the chip modulation unit 3, it is possible to efficiently radiate signal radio waves.

  The first antenna 5 and the second antenna 15 described above may be configured with the same diameter and the same number of turns, or may be configured with different diameters and different numbers of turns. The frequency of radio waves that can be transmitted and received by the first antenna 5 and the second antenna 15 is not limited to a specific frequency as long as communication with the reader / writer 21 is possible, and various frequencies can be used. Of course. For example, a frequency of 13.56 MHz or 2.4 GHz is used.

  Next, the electrical configuration of the RFID chip 40 will be described. The RFID chip 40 is received from the first antenna 5, the chip control unit 2 that controls communication processing, determination processing, display processing, and the like, the chip modulation unit 3 that generates a modulation signal that can be transmitted from the first antenna 5. A chip demodulator 4 that demodulates an electric signal, a chip storage unit 8 that is a nonvolatile storage element, and a chip power supply unit 6 are configured.

  Among these, the chip demodulator 4 is provided for demodulating an electric signal generated by irradiating the first antenna 5 with a signal radio wave, and is electrically connected to the first antenna 5. Further, the chip demodulator 4 is electrically connected to the chip controller 2 so that the demodulated electric signal can be transmitted to the chip controller 2. The chip modulator 3 is provided to modulate the electrical signal transmitted from the chip controller 2 into a modulated signal that can be transmitted via the first antenna 5. The chip modulation unit 3 is electrically connected to the chip control unit 2 and the first antenna 5.

  The modulation method in the chip modulation unit 3 and the demodulation method in the chip demodulation unit 4 are not limited to specific methods, and various conventionally known modulation / demodulation methods are employed. For example, an amplitude modulation (AM) method, a frequency modulation (FM) method, a phase modulation (PM) method, and the like can be given.

  The chip storage unit 8 is provided with a unique ID storage area 9 in which a unique ID is stored. The unique ID is an ID used for specifying the RFID chip 40 and is an ID unique to the RFID chip 40. And it is used in order to identify RFID chip | tips. The chip storage unit 8 is electrically connected to the chip control unit 2 so that the information stored in the chip storage unit 8 can be referred to by the chip control unit 2.

  The chip power supply unit 6 stores a current generated by irradiating the first antenna 5 with the signal radio wave, and stores the chip control unit 2, the chip modulation unit 3, the chip demodulation unit 4, and the chip storage unit 8. It is provided for use as power to be driven.

  In the present embodiment, it is assumed that the RFID tag 1 has a built-in RFID chip 40, but the present invention is not limited to this configuration. Therefore, the above-described functional blocks may be configured by separate devices (CPU, modulation circuit, demodulation circuit, memory, etc.).

  Next, the notification control communication unit 41 will be described. The notification control communication unit 41 includes a notification control unit 12 that controls communication processing, determination processing, display processing, and the like, a notification demodulation unit 14 that demodulates an electrical signal received from the second antenna 15, and a nonvolatile storage element. A notification storage unit 18, an LED 17, and a notification power supply unit 16 are included.

  Among these, the notification demodulator 14 is provided for demodulating an electric signal generated by irradiating the second antenna 15 with a signal radio wave. The notification demodulator 14 is electrically connected to the second antenna 15. In addition, the notification demodulator 14 is electrically connected to the notification controller 12 so that the demodulated electrical signal can be transmitted to the notification controller 12.

  Note that the demodulation scheme in the notification demodulator 14 is not limited to a specific scheme, and various conventionally known modulation / demodulation schemes are employed. For example, an amplitude modulation (AM) method, a frequency modulation (FM) method, a phase modulation (PM) method, and the like can be given.

  The notification storage unit 18 is provided with an identification ID storage area 19 in which an identification ID is stored. The identification ID is an ID used to identify the RFID tags 1 and is used to identify the RFID tags 1 with each other. The notification storage unit 18 is electrically connected to the notification control unit 12 so that the information stored in the notification storage unit 18 can be referred to by the notification control unit 12.

  The LED 17 is electrically connected to the notification control unit 12 so as to be able to switch on / off based on a control signal from the notification control unit 12. In addition, the notification power supply unit 16 stores electric current generated by irradiating the second antenna 15 with signal radio waves, and serves as power for driving the notification control unit 12, the notification demodulation unit 14, the LED 17, and the notification storage unit 18. It is provided for use.

  Next, the power supply configuration of the RFID tag 1 will be described with reference to FIG. As shown in FIG. 3, the chip power supply unit 6 of the RFID chip 40 stores the current generated by the first antenna 5, and the chip control unit 2, the chip modulation unit 3, the chip demodulation unit 4, and the chip storage unit In order to drive 8, power is supplied to these functional blocks. As a result, the RFID chip 40 is driven and executes various processes. In addition, the notification power supply unit 16 of the notification control communication unit 41 stores the current generated in the second antenna 15 and drives the notification control unit 12, the notification demodulation unit 14, the LED 17, and the notification storage unit 18. In addition, power is supplied to these devices. Thereby, each device which comprises the communication part 41 for alerting | reporting control drives, and performs various processes.

  Next, the electrical configuration of the reader / writer 21 will be described with reference to FIG. As shown in FIG. 4, the reader / writer 21 includes a handy reader / writer 51 and an installed reader / writer 52. As shown in FIG. 1, the handy reader / writer 51 irradiates a signal radio wave to the RFID tag 1 attached to the spine of a book from the front side of the bookshelf while being held by the user, and searches for a desired book. Used to do. The installation reader / writer 52 is used for searching for a desired book by irradiating a signal radio wave to the RFID tag 1 attached to the back cover of the book from the back of the bookcase. The handy reader / writer 51 and the installed reader / writer 52 are a communication line 53 (see FIG. 1) connected to the handy reader / writer 51 and a communication line 54 (see FIG. 1) connected to the installed reader / writer 52. It is in a state of being connected to the network 55 via Then, the first control unit 22 that is the control unit of the handy reader / writer 51 and the second control unit 42 that is the control unit of the installed reader / writer 52 can communicate with each other via the network 55. ing.

  As the network 55, various conventionally known networks can be used. For example, the Internet, a local area LAN (intranet), a wireless LAN, and the like can be given. Alternatively, the handy reader / writer 51 and the installed reader / writer 52 may be connected so as to be able to communicate one-on-one. For example, the connection state may be a wired cable (LAN cable, USB (Universal Serial Bus) cable, etc.) or a wireless connection state.

  In this embodiment, the handy reader / writer 51 and the installed reader / writer 52 can communicate with each other via the communication lines 53 and 54. The communication method between each reader / writer and the network 55 is as follows. It is not limited to this method, and various conventionally known communication methods can be used. For example, the structure which can communicate via the network 55 by the radio | wireless communication via an antenna may be sufficient.

  The electrical configuration of the handy reader / writer 51 will be described. The handy reader / writer 51 transmits from the first control unit 22 that controls communication processing, determination processing, and the like, the first R / W antenna 25 configured by an antenna having a loop shape, and the first R / W antenna 25. A first modulation unit 23 that generates a possible modulation signal, a first demodulation unit 24 that demodulates a signal received from the first R / W antenna 25, an input unit 27, and a first storage unit that is a nonvolatile storage element 28.

  The first R / W antenna 25 is a so-called loop antenna. When a radio wave is irradiated, a current can be generated in the first R / W antenna 25 by electromagnetic induction, and an electric signal can be transmitted to the first R / W antenna 25 to obtain a desired signal. Radio waves can be emitted.

  The first R / W antenna 25 has its loop diameter and number of turns adjusted so that a resonance phenomenon occurs at a predetermined frequency. Thereby, when a signal radio wave radiated from the RFID tag 1 is irradiated, an electric signal can be efficiently extracted. Further, when an electric signal is transmitted from the first modulation unit 23, it is possible to efficiently radiate signal radio waves from the first R / W antenna.

  In addition, the first R / W antenna 25 is adjusted in diameter and number of turns of the loop antenna so that signal radio waves can be transmitted and received with the first antenna 5 included in the RFID tag 1. Thus, the first control unit 22 of the handy reader / writer 51 can communicate with the RFID chip 40 in a state where the first antenna 5 is connected.

  Further, the frequency of the radio wave that can be transmitted / received by the first R / W antenna 25 is not limited to a specific frequency as long as communication with the first antenna 5 is possible, and various frequencies can be used. is there. For example, a frequency of 13.56 MHz or 2.4 GHz is used.

  The first demodulator 24 is provided for demodulating an electric signal generated by irradiating the first R / W antenna 25 with radio waves. The first demodulator 24 is electrically connected to the first R / W antenna 25. Further, the first demodulator 24 is electrically connected to the first controller 22 so that the demodulated electrical signal can be transmitted to the first controller 22. The first modulation unit 23 is provided to modulate the electrical signal transmitted from the first control unit 22 into a modulation signal that can be transmitted via the first R / W antenna 25. The first modulation unit 23 is electrically connected to the first control unit 22 and the first R / W antenna 25.

  The modulation method in the first modulation unit 23 and the demodulation method in the first demodulation unit 24 are not limited to a specific method, and various conventionally known modulation / demodulation methods are employed. For example, an amplitude modulation (AM) method, a frequency modulation (FM) method, a phase modulation (PM) method, and the like can be given.

  The input unit 27 is provided for the user to input the book related information of the search book, and is configured by a push button, a touch sensor, or the like.

  The first storage unit 28 is provided with a unique ID assignment information storage area 29. In the unique ID allocation information storage area 29, the unique ID stored in the chip storage unit 8 (see FIG. 2) of the RFID tag 1 is associated with the book related information of the book to which the RFID tag 1 is attached. The unique ID allocation information which is the received information is stored. The unique ID allocation information searches for the unique ID of the RFID chip 40 built in the RFID tag 1 attached to the corresponding book when the book related information of the search book is input by the user via the input unit 27. In order to do so, it is referred to by the first control unit 22. The first storage unit 28 is electrically connected to the first control unit 22 so that the information stored in the first storage unit 28 can be referred to by the first control unit 22.

  Next, the electrical configuration of the installed reader / writer 52 constituting the reader / writer 21 will be described. The installed reader / writer 52 includes a second control unit 42 that performs overall control such as communication processing and determination processing, a second R / W antenna 31 configured by an antenna having a loop shape, and a second R / W antenna 31. The second modulation unit 43 generates a modulation signal that can be transmitted more and a second storage unit 48 that is a nonvolatile storage element.

  The second R / W antenna 31 is a so-called loop antenna. When a radio wave is irradiated, a current can be generated in the second R / W antenna 31 by electromagnetic induction, and an electric signal is transmitted to the second R / W antenna 31 to obtain a desired signal. It is configured to be able to emit radio waves.

  The second R / W antenna 31 has its loop diameter and number of turns adjusted so that a resonance phenomenon occurs at a predetermined frequency. Thereby, when a signal radio wave radiated from the RFID tag 1 is irradiated, an electric signal can be efficiently extracted. Further, when an electric signal is transmitted from the second modulation unit 43, it is possible to efficiently radiate signal radio waves.

  The second R / W antenna 31 is adjusted in diameter and number of turns so that signal radio waves can be transmitted and received with the second antenna 15 included in the RFID tag 1. Thereby, the 2nd control part 42 of the installation reader / writer 52 can communicate with the communication part 41 for notification control of the state to which the 2nd antenna 15 was connected.

  In addition, the frequency of the radio wave that can be transmitted and received by the second R / W antenna 31 is not limited to a specific frequency as long as it can communicate with the second antenna 15, and various frequencies can be used. It is. For example, a frequency of 13.56 MHz or 2.4 GHz is used.

  The second modulator 43 is provided to modulate the electrical signal transmitted from the second controller 42 into a modulated signal that can be transmitted via the second R / W antenna 31. The controller 42 and the second R / W antenna 31 are electrically connected.

  The modulation method in the second modulation unit 43 is not limited to a specific method, and various conventionally known modulation / demodulation methods are employed. For example, an amplitude modulation (AM) method, a frequency modulation (FM) method, a phase modulation (PM) method, and the like can be given.

  The second storage unit 48 is provided with a collation information storage area 49. In the collation information storage area 49, the unique ID stored in the chip storage unit 8 (see FIG. 2) of the RFID chip 40 and the notification in the notification control communication unit 41 of the RFID tag 1 in which the RFID chip 40 is built in. Unique ID-identification ID collation information, which is information associated with the identification ID stored in the storage unit 18, is stored. The unique ID-identification ID collation information is used to search the identification ID of the RFID tag 1 in which the RFID chip 40 having a predetermined unique ID is incorporated, and to turn on the LED 17 included in the RFID tag 1. More referenced. The second storage unit 48 is electrically connected to the second control unit 42 so that each information stored in the second storage unit 48 can be referred to by the second control unit 42.

  Next, the chip control unit 2 of the RFID chip 40 in the RFID tag 1, the notification control unit 12 of the notification control communication unit 41, the first control unit 22 of the handy reader / writer 51, and the second control unit 42 of the installation reader / writer 52. The processing executed by the above will be described with reference to FIGS. FIG. 5 is a flowchart of the RFID tag search process executed by the first control unit 22 of the handy reader / writer 51, and FIG. 6 is a flowchart of the notification process executed by the chip control unit 2 of the RFID tag 1. FIG. 7 is a flowchart of the RFID tag search process executed by the second control unit 42 of the installation reader / writer 52, and FIG. 8 shows the notification process executed by the notification control unit 12 of the RFID tag 1. It is a flowchart.

  The first control unit 22 of the handy reader / writer 51 and the second control unit 42 of the installation reader / writer 52 repeatedly execute the processes shown in FIGS. 5 and 7 when the power is turned on. Further, the chip controller 2 of the RFID chip 40 in the RFID tag 1 irradiates the first antenna 5 with the signal radio wave radiated from the first R / W antenna 25 of the handy reader / writer 51, and the chip power supply unit 6 (see FIG. 3), when the driving power is generated and the power is supplied to the chip controller 2, the processing shown in FIG. 6 is executed. In addition, the notification control unit 12 of the notification control communication unit 41 in the RFID tag 1 irradiates the second antenna 15 with the signal radio wave radiated from the second R / W antenna 31 of the installation reader / writer 52 to notify the notification power supply unit. When drive power is generated at 16 (see FIG. 3) and power is supplied to the notification control unit 12, the processing shown in FIG. 8 is executed.

  As shown in FIG. 5, the first control unit 22 of the handy reader / writer 51 monitors the input unit 27 while the power is turned on, and waits until an input operation is performed by the user via the input unit 27. (S11: NO).

  And when the input operation of the book relevant information relevant to a search book is performed by the user via the input part 27 and this is detected by the 1st control part 22 (S11: YES), the 1st control part 22 is 1st. With reference to the unique ID assignment information stored in the unique ID assignment information storage area 29 of the storage unit 28, the unique ID of the RFID tag 1 attached to the book corresponding to the input search book related information is specified ( S12).

  Next, the radiation surface on which the first R / W antenna 25 in the handy reader / writer 51 is arranged and the signal radio wave is radiated is directed to the bookshelf side by the user. In this state, the first control unit 22 transmits, from the first R / W antenna 25, the unique ID designation signal that designates the unique ID identified in S12 among the RFID tags 1 existing in the signal radio wave radiation range. Therefore, a unique ID designation signal is transmitted to the first modulation unit 23 (S13).

  The unique ID designation signal transmitted from the first control unit 22 is modulated by the first modulation unit 23 to a frequency that can be radiated from the first R / W antenna 25. Then, the modulated unique ID designation signal is radiated from the first R / W antenna 25 as a signal radio wave. The radiated signal radio wave is amplified and transmitted to a transmission power that can be received by the RFID tag 1 attached to the book displayed on the bookshelf.

  On the other hand, in the chip controller 2 constituting the RFID chip 40 of the RFID tag 1, when the first antenna 5 is irradiated with signal radio waves radiated from the first R / W antenna 25 of the handy reader / writer 51, chip power supply is performed. The unit 6 generates electric power necessary for driving the chip control unit 2 and the like. As a result, the chip controller 2 is activated, and the processing in FIG. 6 is started.

  As shown in FIG. 6, the activated chip control unit 2 stands by until a demodulated signal received by the first antenna 5 and demodulated by the chip demodulation unit 4 is received. When the demodulated signal is received and it is determined that the received signal is the unique ID designation signal (S13, see FIG. 5) transmitted from the handy reader / writer 51 (S41: YES), the received unique ID is then received. The unique ID designated by the designation signal is compared with the unique ID stored in the unique ID storage area 9 of the chip storage unit 8.

  When the unique ID designated by the received unique ID designation signal matches the unique ID read from the unique ID storage area 9 of the chip storage unit 8 (S43: YES), the handy reader / writer 51 is contacted. It is necessary to send back a response signal and notify the handy reader / writer 51 that the unique ID designation signal has been received. Therefore, the chip control unit 2 transmits a unique ID response signal including the read unique ID information to the chip modulation unit 3 (S45). Then, the chip control unit 2 of the RFID chip 40 ends the notification process.

  The unique ID response signal transmitted from the chip controller 2 is modulated by the chip modulator 3 to a frequency that can be radiated from the first antenna 5. Then, the modulated unique ID response signal is radiated from the first antenna 5 as a signal radio wave.

  On the other hand, if the demodulated signal is not the unique ID designation signal transmitted from the reader / writer 21 (S41: NO), the chip controller 2 returns to S41 and continues to wait until receiving the unique ID designation signal. Even when the demodulated signal is a unique ID designation signal (S41: YES), the unique ID designated by the received unique ID designation signal and the unique ID storage area 9 of the chip storage unit 8 are read. When the unique ID does not match (S43: NO), the chip controller 2 ends the notification process.

  In the above process, it is determined whether or not the unique ID designated by the received unique ID designation signal matches the unique ID read from the unique ID storage area 9 of the chip storage unit 8. However, the determination method is not limited to this method. Accordingly, the chip controller 2 of the RFID chip 40 indicates that the reader / writer 21 has received the unique ID designation signal when the relationship between the received unique ID and the read unique ID is in accordance with a predetermined rule. It may be determined that notification is necessary, and a unique ID response signal may be transmitted to the chip modulation unit 3.

  On the other hand, as shown in FIG. 5, the first control unit 22 of the handy reader / writer 51 after transmitting the unique ID designation signal (see S <b> 13) continues to receive the unique ID response signal from the RFID tag 1. The ID designation signal transmission process is repeated (S15: NO → S13). Then, the first R / W antenna 25 receives the signal radio wave from the RFID tag 1, is demodulated by the first demodulator 24, and the demodulated signal resulting from the demodulation is based on the processing of S45 (see FIG. 6). If the response is a unique ID response signal transmitted from the RFID tag 1 (S15: YES), the first control unit 22 then identifies the unique ID included in the received unique ID response signal and the unique ID identified in S12. ID is compared (S17). If the two match (S17: YES), the search book and the search RFID tag 1 exist within the radio wave emission range of the unique ID designation signal radiated from the first R / W antenna 25 of the handy reader / writer 51. Judge that you are doing.

  On the other hand, even when the demodulated demodulated signal is a unique ID response signal (S15: YES), if the included unique ID does not match the unique ID specified in S12 (S17: NO), The RFID tag attached to the book not to be searched does not exist within the radiation range of the signal radio wave emitted from the first R / W antenna 25 of the handy reader / writer 51 and the search RFID tag 1 does not exist. The unique ID returned from 1 is determined to be a reply signal. In such a case, the direction of the handy reader / writer 51 is adjusted by the user, and the radiation direction of the radio wave is changed. And it returns to S13 and the above-mentioned process is repeatedly performed until it will be in the state in which the search book and the search RFID tag 1 exist in the radiation range of a signal radio wave.

  In the above-described process, it is determined whether or not the received unique ID matches the unique ID searched in S12, but the determination method is not limited to this method. Therefore, the first control unit 22 of the handy reader / writer 51 specifies the unique ID radiated from the handy reader / writer 51 when the relationship between the received unique ID and the unique ID specified in S12 conforms to a predetermined rule. It may be determined that the search book and the search RFID tag 1 exist within the radio wave emission range of the signal.

  If it is determined in S17 that the search book and the search RFID tag 1 exist in the radiation range of the unique ID designated radio wave radiated from the handy reader / writer 51 (S17: YES), then the first control unit 22 Instructs the installation reader / writer 52 to transmit an identification ID designation signal to turn on the LED provided in the search RFID tag 1 (S19). Specifically, an identification ID transmission instruction packet specifying the fixed ID specified in S12 is transmitted to the second control unit 42 of the installation reader / writer 52 via the network 55. And the 1st control part 22 returns to S11, and repeats the above-mentioned process.

  On the other hand, as shown in FIG. 7, the second control unit 42 of the installed reader / writer 52 continuously monitors packets received from the network 55 in a state where the power is turned on. And it waits until the packet of the transmission instruction | indication of an identification ID designation | designated signal is received from the handy reader / writer 51 (S31: NO).

  If the packet transmitted from the handy reader / writer 51 is received based on the processing of S19 (see FIG. 5) and is determined to be a packet for transmitting an identification ID designation signal (S31: YES), the second The control unit 42 identifies the RFID tag 1 including the RFID chip 40 with the unique ID specified in the received packet as the search RFID tag 1. Then, in order to turn on the LED 17 of the search RFID tag 1, the identification ID corresponding to the unique ID is searched and specified. Specifically, it refers to the unique ID-identification ID collation information stored in the collation information storage area 49 of the second storage unit 48, and corresponds to the unique ID specified in the received packet from the handy reader / writer 51. The identification ID is specified as the identification ID of the search RFID tag 1 (S33).

  Next, the second control unit 42 transmits an identification ID designation signal designating the identification ID of the search RFID tag 1 to the second modulation unit 43 in order to turn on the LED 17 included in the search RFID tag 1 (S35). The transmitted identification ID designation signal is modulated by the second modulator 43 to a frequency that can be radiated from the second R / W antenna 31. Then, the modulated identification ID designation signal is radiated from the second R / W antenna 31 as a signal radio wave. The radiated signal radio wave is amplified and transmitted to a transmission power that can generate power necessary for lighting the LED 17 by the search RFID. Here, since the installed reader / writer 52 is disposed in the vicinity of the RFID tag 1, it is possible to transmit the signal with the transmission power suppressed as much as possible. Thereafter, the second control unit 42 returns to S31 and repeatedly executes the above-described processing.

  On the other hand, in the notification control unit 12 constituting the notification control communication unit 41 of the RFID tag 1, when the second antenna 15 is irradiated with the signal radio wave radiated from the second R / W antenna 31 of the installation reader / writer 52, The notification power supply unit 16 generates power necessary for driving the notification control unit 12 and the like. As a result, the notification control unit 12 is activated, and the processing in FIG. 8 is started.

  As shown in FIG. 8, the activated notification control unit 12 first waits until it receives the demodulated signal received by the second antenna 15 and demodulated by the notification demodulation unit 14 (S61: NO). ). If the demodulated signal is received and it is determined that the received signal is the identification ID designation signal (S35, see FIG. 7) transmitted from the installation reader / writer 52 (S61: YES), then the notification storage unit 18 The identification ID stored in the identification ID storage area 19 is compared with the identification ID designated by the received identification ID designation signal.

  When the identification ID designated by the received identification ID designation signal matches the read identification ID (S63: YES), the notification control unit 12 turns on the LED 17 from the installation reader / writer 52. It is determined that an instruction to that effect has been made, and the LED 17 is turned on (S65). Then, the notification control unit 12 ends the RFID tag search process.

  The power necessary for lighting the LED 17 is generated by the notification power supply unit 16 based on the signal radio wave irradiated to the second antenna 15 from the second R / W antenna 31 of the installation reader / writer. . Here, the signal radio wave radiated from the second R / W antenna 31 is transmitted after being adjusted to an intensity sufficient to generate power necessary for turning on the LED 17 by the RFID tag 1. Therefore, the notification control unit 12 can turn on the LED 17 using the power generated by the notification power supply unit 16.

  On the other hand, when the identification ID specified by the received identification ID designation signal does not match the identification ID read from the identification ID storage area 19 of the notification storage unit 18 (S63: NO) , It is determined that it is not the RFID tag searched by the reader / writer 21. In this case, since it is not necessary to turn on the LED 17, the notification process is terminated without performing any special process.

  As described above, in the present embodiment, the RFID tag 1 is attached by turning on the LED 17 of the RFID tag 1 using the reader / writer 21 (the handy reader / writer 51 and the installed reader / writer 52). Can be recognized as a search book. Here, the reader / writer 21 first transmits a unique ID designation signal to confirm whether or not the search RFID exists within the signal radio wave radiation range, and after confirming that the search RFID exists, the identification ID The designation signal is transmitted to turn on the LED 17 included in the search RFID. As a result, the reader / writer does not need to continuously transmit the transmission radio wave of the power necessary for generating the power for turning on the LED 17 by the RFID tag 1, so that the power consumption of the reader / writer 21 can be reduced.

  Further, the power for turning on the LED 17 by the RFID tag 1 is generated based on the signal radio wave radiated from the second R / W antenna 31 provided in the installation reader / writer 52. Here, since the installed reader / writer 52 is disposed in the vicinity of the RFID tag 1, even when a relatively small output signal radio wave is radiated, the RFID tag generates power necessary for lighting the LED 17. Is possible. Thereby, the installation reader / writer 52 can turn on the LED 17 with the RFID tag while suppressing the power of the signal radio wave to be radiated as much as possible. As a result, the power consumption of the reader / writer 21 can be further suppressed.

  Furthermore, it is possible to determine whether or not the search RFID tag 1 exists in the radiation area of the signal radio wave radiated from the handy reader / writer 51. This allows the reader / writer to check in advance whether or not the desired RFID tag exists nearby, so that the user can confirm that the desired RFID tag is within the radio wave emission range emitted from the reader / writer. It is possible to confirm in advance and cause the RFID tag to perform notification. Therefore, even if a state in which the user has overlooked the RFID tag is generated even though the RFID tag is reporting from the notification means, the user has a desired RFID tag in the vicinity. Therefore, it is possible to reliably search for the RFID tag.

  The first antenna 5 in FIG. 2 corresponds to the “first tag antenna” of the present invention, the second antenna 15 corresponds to the “second tag antenna” of the present invention, and the notification storage unit 18 The chip storage unit 8 corresponds to the “chip storage unit” of the present invention, the LED 17 corresponds to the “tag notification unit” of the present invention, and the notification power supply unit 16 corresponds to the “tag storage unit” of the present invention. Corresponds to the “tag power supply means” of the present invention. In addition, in S61 of FIG. 8, the notification control unit 12 that performs a process of receiving the signal demodulated by the notification demodulation unit 14 corresponds to the “tag receiving unit” of the present invention, and turns on the LED 17 in S65. The notification control unit 12 that performs control corresponds to the “tag control means” of the present invention. 6 is equivalent to the “chip receiving means” of the present invention, and the chip modulation unit is selected in S45. The chip control unit 2 performs the process of receiving the signal demodulated by the chip demodulation unit 4 in S41. The chip control unit 2 that performs a process of transmitting a signal to 3 and transmitting a modulated signal from the first antenna 5 corresponds to the “chip transmitting means” of the present invention.

  The first storage unit 28 shown in FIG. 4 corresponds to the “R / W storage unit” of the present invention. In S13 of FIG. 5, the first storage unit 28 transmits a signal to the first modulation unit 23, and the first R / W antenna. 25, the first control unit 22 that performs the process of transmitting the modulated signal corresponds to the “first R / W transmission unit” of the present invention, and the signal demodulated by the first demodulation unit 24 in S15 The first control unit 22 that performs the receiving process corresponds to the “first R / W receiving unit” of the present invention, and transmits a signal to the second modulation unit 43 in S35 of FIG. The second control unit 42 that performs the process of transmitting the modulation signal from the antenna 31 corresponds to the “second R / W transmission unit” of the present invention.

  In addition, this invention is not limited to the said embodiment, A various change is possible.

  In the above-described embodiment, the RFID tag 1 includes the LED 17 as a notification unit, but the notification unit is not limited to the LED. Therefore, the structure provided with the device (buzzer etc.) for implement | achieving another alerting | reporting means may be sufficient.

  In the above-described embodiment, the installation reader / writer 52 is used by being installed on the back of the bookcase, but the present invention is not limited to this configuration. The installation reader / writer 52 may be installed in another place or may be movably provided that it can transmit a signal radio wave with an intensity capable of turning on the LED 17 included in the RFID tag 1. Absent.

  In the above-described embodiment, when the RFID tag 1 receives the identification designation signal, the notification power supply unit 16 generates power, and the LED 17 is turned on by the generated power. However, the LED 17 is turned on. Therefore, the method for generating the power necessary for this is not limited to this method. Therefore, the installation reader / writer 52 first transmits a radio wave necessary for lighting the LED 17 to the RFID tag 1, and after generating sufficient power to light the LED 17 in the RFID tag 1, the identification ID designation signal Can be sent. By this method, the installation reader / writer 52 has an effect that the transmission power of the signal radio wave of the identification ID designation signal can be suppressed. In this case, the radio wave required for lighting the LED 17 may be a modulated signal radio wave or an unmodulated radio wave.

It is a schematic diagram of a book search system. 1 is a schematic diagram showing an electrical configuration of an RFID tag 1. 2 is a schematic diagram showing a power supply configuration of the RFID tag 1. FIG. 2 is a schematic diagram showing an electrical configuration of a reader / writer 21. FIG. It is a flowchart of the RFID tag search process performed in the 1st control part 22 of the handy reader / writer 51. 5 is a flowchart of notification processing executed by the chip control unit 2 of the RFID tag 1. 7 is a flowchart of RFID tag search processing executed by the second control unit 42 of the installed reader / writer 52. 4 is a flowchart of a notification process executed by a notification control unit 12 of the RFID tag 1.

Explanation of symbols

1 RFID tag 2 Chip control unit 3 Chip modulation unit 4 Chip demodulation unit 5 First antenna 6 Chip power supply unit 8 Chip storage unit 12 Notification control unit 14 Notification demodulation unit 15 Second antenna 16 Notification power supply unit 17 LED
18 Notification storage unit 21 Reader / writer 22 First control unit 23 First modulation unit 24 First demodulation unit 25 First R / W antenna 27 Input unit 28 First storage unit 31 Second R / W antenna 40 RFID chip 41 Notification control Communication unit 42 second control unit 43 second modulation unit 48 second storage unit 50 RFID tag system 51 handy reader / writer 52 installed reader / writer 53 network

Claims (2)

An RFID tag system that searches for a desired RFID tag using a reader / writer,
RFID tags
An RFID chip;
An antenna connected to the RFID chip, which supplies an electric signal generated when the signal radio wave transmitted from the reader / writer is irradiated to the RFID chip and also transmits the electric signal transmitted from the RFID chip. A first tag antenna, which is an antenna that transmits as radio waves,
A second tag antenna that is an antenna different from the first tag antenna;
Tag storage means for storing an identification ID which is an ID for identifying the RFID tag;
Tag receiving means for demodulating and receiving an electrical signal generated when the signal radio wave transmitted from the reader / writer is irradiated to the second tag antenna;
Tag notification means for performing notification,
Tag control means for controlling the tag notification means and executing notification based on the signal demodulated and received by the tag reception means;
Tag power supply means for supplying power for driving the tag reception means, the tag notification means, and the tag control means, and the second tag antenna is irradiated with a signal radio wave transmitted from a reader / writer Tag power supply means for generating power from an electrical signal generated in the case,
The RFID chip is
Chip storage means for storing a unique ID which is an ID for identifying the RFID chip;
Chip receiving means for demodulating and receiving an electrical signal generated by the first tag antenna;
Chip transmitting means for transmitting a modulated electric signal to the first tag antenna and transmitting signal radio waves from the first tag antenna;
Reader / writer
R / W storage means for storing an identification ID for identifying the RFID tag and a unique ID for identifying the RFID chip in association with each other;
A first R / W antenna that transmits and receives signal radio waves using a frequency that can be transmitted and received by the first tag antenna;
First R / W transmitting means for transmitting a modulated signal as a signal radio wave from the first R / W antenna;
First R / W receiving means for demodulating and receiving an electrical signal generated in the first R / W antenna;
An antenna that transmits and receives signal radio waves using a frequency that can be transmitted and received by the second tag antenna, and a distance between the RFID tag and a distance between the first R / W antenna and the RFID tag A second R / W antenna, which is an antenna arranged at a shorter position,
An RFID tag system comprising: a second R / W transmission unit configured to transmit a modulated signal as a signal radio wave from the second R / W antenna. The reader / writer is
After modulating a unique ID designation signal, which is a signal designating a unique ID for identifying the RFID chip incorporated in a desired RFID tag, the first R / W transmission means Send
The RFID tag is
The electric signal generated by the first tag antenna is demodulated and received by the chip receiving means,
The signal demodulated and received by the chip receiving means is a unique ID designation signal, the unique ID designated by the unique ID designation signal, and the unique ID stored in the chip storage means If the predetermined relationship is satisfied, the response signal is modulated and transmitted by the chip transmitting means,
The reader / writer is
When the response signal returned from the desired RFID tag in response to the unique ID designation signal transmitted by the first R / W transmission means is demodulated and received by the first R / W reception means, the response signal The identification ID of the RFID tag that has transmitted is extracted with reference to the R / W storage means,
After modulating the identification ID designation signal which is a signal designating the extracted identification ID, the second R / W transmission means transmits to the RFID tag,
In the RFID tag,
By irradiating the second tag antenna with the signal radio wave transmitted by the second R / W transmission unit of the reader / writer, the tag power supply unit includes the tag reception unit, the tag notification unit, and the After generating power to drive the tag control means,
The tag receiving means
Demodulate and receive the electrical signal generated by the second tag antenna,
The resulting signal demodulated and received by the tag receiving means is an identification ID designation signal which is a signal designating an identification ID, and the identification ID and the identification ID stored in the tag storage means 2. The RFID tag system according to claim 1, wherein the tag control unit controls the tag notification unit to perform notification when the predetermined relationship is satisfied.

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