JP2009230512A - Rfid tag reader - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an RFID tag reader with a wide reading range. <P>SOLUTION: A control unit 100 generates a control signal for selecting an antenna unit 200 and transmits the control signal to the antenna unit 200. Each antenna unit 200 performs impedance matching of a matching circuit 212 on the basis of the control signal for antenna selection when its own antenna unit 200 is selected, and controls impedance matching of the matching circuit 212 so as to be unmatched when its own antenna unit 200 is not selected. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an RFID tag reader that reads a unique identifier preset in an RFID tag in a non-contact manner from an RFID tag attached to a distribution item in a field such as physical distribution.

This type of RFID tag reader (hereinafter simply referred to as “reader”) is an essential component of an antenna for communication with an RFID tag and a high-frequency circuit connected to the antenna. For these components, various mounting forms are adopted depending on the intended use of the reader. For example, as shown in Patent Document 1, when the purpose is to read an RFID tag attached to a product displayed on a store shelf, the top surface or the bottom surface of the shelf plate has substantially the same area as the shelf plate. A thin antenna unit is attached. The high-frequency circuit is housed in a housing attached to an appropriate location on the shelf. The high frequency circuit and the antenna unit are connected by a coaxial cable having a predetermined characteristic impedance. The antenna unit includes a loop antenna and a matching circuit for impedance matching. In such a reading apparatus, the unique identifiers of the RFID tags are sequentially read for a number of products displayed on the shelf, and the read data is transmitted to a device such as a computer.
JP 2001-118037 A

  By the way, when reading the RFID tag of the product displayed on the shelf as described above, a plurality of antenna units are associated with one shelf in order to recognize which position is the RFID tag of the product placed on the shelf. Need to be installed side by side. Similarly, when a shelf area is large, a plurality of antenna units may be installed side by side. Furthermore, instead of arranging a plurality of antenna units, a plurality of loop antennas may be provided side by side within one antenna unit. When the reading apparatus has a plurality of antennas as described above, the reading apparatus sequentially repeats the reading process for each antenna.

  However, when power is supplied to a certain antenna for communication with an RFID tag, there is a problem that the reading range of the desired antenna is narrowed by interference with another antenna adjacent to the antenna.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an RFID tag reader having a wide reading range.

  In order to achieve the above object, the present invention includes a plurality of antennas for communication with an RFID tag, a high-frequency circuit for processing a signal for communication with the RFID tag, and a signal line for connecting the antenna and the high-frequency circuit. In the RFID tag reader provided, a control means for outputting a control signal for antenna selection, a matching means for matching impedance of the high frequency signal to the antenna, and a high frequency signal for the antenna selected by the control signal by the control means And matching control means for controlling non-matching of high-frequency signal impedance for non-selected antennas, while impedance matching of high-frequency signals is being performed for one antenna. Does not match the impedance matching of high frequency signals to other antennas adjacent to the antenna. And wherein the Rukoto.

  According to the present invention, when one antenna among a plurality of antennas is selected, impedance matching of the antenna is achieved, and impedance matching of other antennas adjacent to the antenna is mismatched. Thereby, it can prevent that the electromagnetic field formed with one antenna couple | bonds with the other adjacent antenna. Such coupling generally narrows the formation range of the electromagnetic field formed by one antenna. Therefore, according to the present invention, it is possible to prevent the reading range of the RFID tag from being narrowed.

  An example of the specific operation of the matching control means is one that changes the circuit constant in the matching means. Moreover, as an example of a preferred aspect of the present invention, there is one characterized in that a pair of matching means / matching control means is provided for each antenna. Furthermore, as another example of a preferable aspect of the present invention, there is one characterized in that the number of antennas selected simultaneously among a plurality of antennas is one. Furthermore, as another example of a preferred aspect of the present invention, each antenna is composed of a loop antenna and is arranged so that a part of the loop of one antenna overlaps a part of the loop of the adjacent antenna. The characteristic is mentioned.

  Further, as an example of a preferred aspect of the present invention, a superimposing unit that superimposes the control signal on a high-frequency signal output from a high-frequency circuit to an antenna, and a superimposing signal input from the superimposing unit via a signal line And a separation means for separating the signal and the control signal and supplying the separated high-frequency signal to the matching circuit and supplying the separated control signal to the matching control means.

  According to the present invention, since the control signal for antenna selection is transmitted by being superimposed on the signal line for transmitting the high frequency signal, it is not necessary to separately provide a signal line for transmitting the control signal. Thereby, installation property improves.

  As described above, according to the present invention, when one antenna among a plurality of antennas is selected, impedance matching of the antenna is achieved, and impedance matching of other antennas adjacent to the antenna is mismatched. Thereby, it can prevent that the electromagnetic field formed with one antenna couple | bonds with the other adjacent antenna. Such coupling narrows the formation range of the electromagnetic field formed by one antenna. Therefore, according to the present invention, narrowing of the reading range of the RFID tag can be prevented.

(First embodiment)
An RFID tag reader according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an overall configuration diagram of an RFID tag reader, and FIG. 2 is a functional block diagram of a control unit.

  The reading device according to the present embodiment is used for reading a unique number as a unique identifier of the RFID tag 11 from the RFID tag 11 attached to the product 10 displayed in the showcase 1.

  The showcase 1 includes a plurality of product shelves 2 for displaying the products 10 and a cooling mechanism (not shown) for cooling the products 10. Since the cooling mechanism is the same as that conventionally known, the description thereof is omitted here. A plurality (four in this embodiment) of antenna units 200 a to 200 d for communicating with the RFID tags 11 of the displayed products 10 are provided on the upper surface of each product shelf 2. The antenna units 200 a to 200 d are arranged side by side in the left-right direction on the upper surface of each product shelf 2. The showcase 1 also includes a control unit 100 connected to the antenna units 200a to 200d via coaxial cables 400a to 400d, and a centralized control device 300 that centrally controls each control unit 100. The control unit 100 reads a unique number preset for the tag from the RFID tag 11 using each of the antenna units 200a to 200d to be connected. The centralized control device 300 totals the unique numbers of the RFID tags 11 read by the control units 100 and transmits the totaled data to the computer 50 installed in the store. The RFID tag reader according to the present embodiment is one in which the control unit 100 and the antenna units 200a to 200d are connected by coaxial cables 400a to 400d.

  As shown in FIG. 2, the control unit 100 includes a communication interface 101 for connecting to the centralized control device 300, a tag communication control unit 102 that controls communication with the RFID tag 11, and an output of the tag communication control unit 102. A modulation circuit 111 that modulates a signal into a high-frequency signal, an oscillation circuit 112 that generates a carrier wave, an amplification circuit 120 that amplifies the high-frequency signal, and a DC bias application circuit 130 that applies a DC bias to the high-frequency signal from the amplification circuit 120 It has. The control unit 100 also includes an amplifier circuit 140 that amplifies the high-frequency signal received from each of the antenna units 200a to 200d, and a demodulation circuit 113 that demodulates the communication signal from the high-frequency signal. Furthermore, the control unit 100 includes a control signal generation unit 150 that generates a control signal for selecting the antenna units 200a to 200d. The modulation circuit 111, the demodulation circuit 113, and the oscillation circuit 112 are mounted on a dedicated communication IC 110.

  The control signal generation unit 150 generates and transmits a control signal for antenna selection based on a selection instruction for the antenna units 200a to 200d from the tag communication control unit 102. The antenna selection control signal is a DC signal having a voltage value corresponding to each antenna unit 200a to 200d, and the voltage value corresponding to each antenna unit 200a to 200d is a different value. The DC bias application circuit 130 applies a DC bias to the high frequency signal from the amplifier circuit 120 with the voltage value of the control signal from the control signal generator 150. In other words, the DC bias applying circuit 130 superimposes the control signal on the high frequency signal.

  Next, the structure of each antenna unit 200a-200d is demonstrated with reference to FIG.3 and FIG.4. FIG. 3 is a top view for explaining the internal structure of the antenna unit, and FIG. 4 is a functional block diagram of the antenna unit. In addition, since each antenna unit 200a-200d is the same, the subscript of the code | symbol was abbreviate | omitted in FIG.3 and FIG.4.

  As shown in FIG. 3, the antenna unit 200 includes a loop antenna 202 provided inside a thin box-shaped housing 201 and a matching circuit unit 210 to which the loop antenna 202 is connected. The loop antenna 202 is made of a metal member such as copper foil or copper wire, for example, and is arranged so as to draw a rectangle along the inner edge of the housing 201. A coaxial cable 400 is connected to the matching circuit unit 210 via a connector (not shown).

  As shown in FIG. 4, the matching circuit unit 210 includes an AC / DC separation circuit 211, a matching circuit 212, a control signal identification circuit 213 that identifies a control signal, and an impedance adjustment circuit 214 that performs constant control of the matching circuit 212. It has.

  The AC / DC separation circuit 211 separates the signal received from the control unit 100 into a DC component and an AC component. The separated DC component voltage is a bias value applied by the DC bias application circuit 130 of the control unit 100. This bias value is the voltage value of the control signal for antenna selection as described above. On the other hand, the separated AC component is a high-frequency signal output from the amplifier circuit 120 on the transmission side. Therefore, the AC / DC separation circuit 211 functions as a separation circuit for the high-frequency signal and the control signal for antenna selection.

  The control signal identification circuit 213 identifies whether the antenna selection control signal separated by the AC / DC separation circuit 211 has selected its own antenna unit 200. Specifically, the control signal identification circuit 213 of each of the antenna units 200a to 200d holds the voltage value of the control signal corresponding to its own antenna unit as a constant, and compares the voltage value with the antenna selection control signal. Identification processing is performed by comparison using a circuit or the like.

  The impedance adjustment circuit 214 controls the circuit constant of the matching circuit 212 so that the impedance matching of the loop antenna 202 can be obtained when the control signal for the antenna selection in the control signal identification circuit 213 corresponds to its own antenna unit 200. To do. On the other hand, when the antenna selection control signal does not correspond to its own antenna unit 200 in the control signal identification circuit 213, the impedance adjustment circuit 214 causes the impedance matching of the loop antenna 202 to be mismatched. Control circuit constants.

  Next, the central control apparatus 300 will be described with reference to FIG. FIG. 5 is a functional block diagram of the central control apparatus. As shown in FIG. 5, the central control apparatus 300 includes a communication interface 301 for connecting to the control unit 100, a communication interface 302 for connecting to the computer 50, and the RFID tag 11 received from each control unit 100. A relay processing unit 303 that counts and transmits the unique number to the computer 50, and a storage unit 304 that is used in the unique number counting process in the relay processing unit 303. The relay processing unit 303 sequentially requests data transmission to the connected control unit 100, receives the unique number of the RFID tag 11 from each control unit 100, and temporarily stores it in the storage unit 304. Then, the relay processing unit 303 transmits information stored in the storage unit 304 to the computer 50. Here, the relay processing unit 303 transmits the data to the computer 50 only when the stored data is changed. That is, the relay processing unit 303 transmits only difference information to the computer 50.

  Next, the reading operation of the RFID tag 11 in this reading apparatus will be described. First, the tag communication control unit 102 instructs the control signal generation unit 150 to select one of the antenna units 200a to 200d. Here, it is assumed that the antenna unit 200a is selected. The tag communication control unit 102 outputs a communication message in accordance with a protocol for communication with the RFID tag 11. The output signal of the tag communication control unit 102 is modulated by the modulation circuit 111 into a carrier wave supplied from the oscillation circuit 112. The high frequency signal output from the modulation circuit 111 is amplified by the amplifier circuit 120. On the other hand, the control signal generation unit 150 outputs a control signal having a voltage value corresponding to the selected antenna unit 200a based on the selection instruction from the tag communication control unit 102. As a result, the high frequency signal from the amplifier circuit 120 is DC biased by the DC bias applying circuit 130 by the voltage value of the antenna selection control signal. The high frequency signal output from the DC bias applying circuit 130 is transmitted to the antenna units 200a to 200d via the coaxial cable 400. FIG. 6 shows a high-frequency signal output from the amplifier circuit 120. FIG. 7 shows a control signal output from the control signal generation unit 150. FIG. 8 shows a transmission signal output from the DC bias application circuit 130.

  The high-frequency signal transmitted to each of the antenna units 200a to 200d is separated into a DC signal and an AC signal in the AC / DC separation circuit 211. This DC signal corresponds to the DC bias applied by the DC bias applying circuit 130, that is, the antenna selection control signal. The voltage value of the antenna selection control signal corresponds to any one of the antenna units 200a to 200d. The control signal identification circuit 213 identifies whether it corresponds to its own antenna unit based on the voltage value of the antenna selection control signal. When it is identified that the own antenna unit is selected, the impedance adjustment circuit 214 performs impedance matching between the matching circuit 212 and the loop antenna 202. On the other hand, when it is identified that another antenna unit is selected, the impedance adjustment circuit 214 causes the matching circuit 212 to have an impedance mismatch with the loop antenna 202. Thereby, when the own antenna unit is selected, the high-frequency signal separated in the AC / DC separation circuit 211 is radiated from the loop antenna 202. On the other hand, when the own antenna unit is selected, the radiation of the high-frequency signal from the loop antenna 202 is weakened to the extent that communication with the RFID tag 11 is impossible.

  The RFID tag 11 that has received the high-frequency signal operates using the high-frequency signal as a power source and generates a response signal. This response signal is received by the loop antenna 202 of the antenna unit 200a. The response signal received by the loop antenna 202 is input to the receiving-side amplifier circuit 140 via the matching circuit 212, the AC / DC separation circuit 211, and the coaxial cable 400. The high frequency signal amplified by the amplifier circuit 140 is demodulated by the demodulation circuit 113. The demodulated signal is input to the tag communication control unit 102.

  Through the above operation, the communication process with the RFID tag 11 using one antenna unit 200a is completed. The tag communication control unit 102 can perform communication processing using all the antenna units 200a to 200d by sequentially switching the antenna unit 200a to be selected to the other antenna units 200b to 200d and repeating the above processing.

  What should be noted here is that the impedance matching of the matching circuit 212 is mismatched in the other antenna units 200a to 200d adjacent to the selected antenna unit 200a to 200d, and thus the selected antenna units 200a to 200d. The electromagnetic field formed by the loop antenna 202 is difficult to be influenced by the loop antenna 202 of the other antenna units 200a to 200d. Thereby, narrowing of the reading range of the RFID tag 11 in each of the antenna units 200a to 200d can be prevented.

  As described above, according to the RFID tag reader according to the present embodiment, it is possible to prevent interference between the antenna unit used in the reading process and another antenna unit even when the plurality of antenna units 200a to 200d are provided. Therefore, narrowing of the reading range can be prevented. In the RFID tag reader according to the present embodiment, the high frequency signal for communication with the RFID tag 11 and the antenna selection control signal can be transmitted with one coaxial cable 400, so that installation workability is improved.

(Second Embodiment)
Next, an RFID tag reader according to a second embodiment of the present invention will be described with reference to FIG. FIG. 9 is a functional block diagram of the antenna unit.

  The difference between the present embodiment and the first embodiment is the configuration of the antenna unit. Since other configurations are the same as those of the first embodiment, only the differences will be described here.

  The antenna unit 200 includes a loop antenna 202 and a matching circuit unit 210 as in the first embodiment. The matching circuit unit 210 turns on / off the electrical connection in the high frequency band of the AC / DC separation circuit 211, the matching circuit 212, the control signal identification circuit 213 for identifying the control signal, and the matching circuit 212 and the loop antenna 202. A switch circuit 215 and a switch control circuit 216 for controlling the switch circuit 215 are provided. The AC / DC separation circuit 211 and the control signal identification circuit 213 are the same as those in the first embodiment. The matching circuit 212 is adjusted so that impedance matching can be achieved when the loop antenna 202 is connected by the switch circuit 215.

  The switch circuit 215 includes a switching element such as a transistor, for example, and turns on or off the connection of both or one of both terminals of the loop antenna 202. Here, when the connection is released, at least one terminal of the loop antenna 202 is in an open state. It should be noted that this can be interpreted as a mismatch of impedance matching with the loop antenna 202.

  The switch control circuit 216 controls the switch circuit 215 so that the loop antenna 202 is connected when the antenna selection control signal corresponds to the own antenna unit 200 in the control signal identification circuit 213. On the other hand, the switch control circuit 216 controls the switch circuit 215 so that the connection with the loop antenna 202 is disconnected when the control signal identifying circuit 213 does not correspond to the antenna unit 200 of the antenna selection control signal. To do.

  According to the RFID tag reader according to the present embodiment, similarly to the first embodiment, the antenna unit and other antennas used in the reading process even when the antenna units 200a to 200d are provided. Since the interference with the unit can be prevented, the reading range can be prevented from being narrowed. In the RFID tag reader according to the present embodiment, the high frequency signal for communication with the RFID tag 11 and the antenna selection control signal can be transmitted with one coaxial cable 400, so that installation workability is improved.

  Although the switch circuit 215 cuts both or one of the terminals of the loop antenna 202, the switch circuit 215 may cut the midpoint of the loop in the loop antenna 202.

(Third embodiment)
An RFID tag reader according to a third embodiment of the present invention will be described with reference to FIGS. FIG. 10 is a functional block diagram of the control unit, and FIG. 11 is a functional block diagram of the antenna unit.

  This embodiment is different from the first embodiment in an antenna selection control signal transmission method. Since other configurations are the same as those of the first embodiment, only the differences will be described here.

  As shown in FIG. 10, the control unit 100 includes a communication interface 101 for connecting to the centralized control device 300, a tag communication control unit 102 that controls communication with the RFID tag 11, and an output of the tag communication control unit 102. A modulation circuit 111 that modulates a signal into a high-frequency signal, an oscillation circuit 112 that generates a carrier wave, and an amplification circuit 120 that amplifies the high-frequency signal are provided. The control unit 100 also includes an amplifier circuit 140 that amplifies the high-frequency signal received from each of the antenna units 200a to 200d, and a demodulation circuit 113 that demodulates the communication signal from the high-frequency signal. Furthermore, the control unit 100 includes a control signal generation unit 151 that generates a control signal for selecting the antenna units 200a to 200d.

  The control signal generation unit 151 generates and transmits a control signal for antenna selection based on the selection instruction of the antenna units 200a to 200d from the tag communication control unit 102. The antenna selection control signal is a digital signal corresponding to each of the antenna units 200a to 200d. The output signal of the control signal generation unit 151 is transmitted to the antenna units 200a to 200d through the control signal cables 410a to 410d corresponding to the antenna units 200a to 200d. The control signal cables 410a to 410d include DC power supply lines (not shown) for the antenna units 200a to 200d. That is, the control unit 100 supplies DC power to each of the antenna units 200a to 200d.

  As shown in FIG. 11, the matching circuit unit 210 of the antenna unit 200 includes a matching circuit 212, a control signal identification circuit 213 that identifies a control signal, and an impedance adjustment circuit 214 that performs constant control of the matching circuit 212. Yes. A coaxial cable 400 is directly connected to the matching circuit 212. A control signal cable 410 is directly connected to the control signal identification circuit 213. Further, the power supply line accommodated in the control signal cable 410 is connected to the control signal identification circuit 213 and the impedance adjustment circuit 214.

  The control signal identification circuit 213 identifies whether the digitized antenna selection control signal transmitted by the control signal cable 410 is the one that has selected its own antenna unit 200.

  In the RFID tag reader according to the present embodiment, the amount of wiring between the control unit 100 and the antenna unit 200 is increased as compared with the first embodiment, while the circuits of the control unit 100 and the antenna unit 200 are provided. It can be simplified. Other operations and effects are the same as those of the first embodiment.

  In this embodiment, the modification of the first embodiment has been described. However, the same modification can be applied to the RFID tag reading apparatus according to the second embodiment.

(Fourth embodiment)
An RFID tag reader according to a fourth embodiment of the present invention will be described with reference to FIGS. FIG. 12 is a functional block diagram of the control unit, and FIG. 13 is a functional block diagram of the antenna unit.

  This embodiment is different from the first embodiment in an antenna selection control signal transmission method. Further, the present embodiment is different from the third embodiment in the power supply method to the antenna unit. Other configurations are the same as those in the first and third embodiments, and only the differences will be described here.

  As illustrated in FIG. 12, the control unit 100 includes a communication interface 101 for connecting to the centralized control device 300, a tag communication control unit 102 that controls communication with the RFID tag 11, and an output of the tag communication control unit 102. A modulation circuit 111 that modulates a signal into a high-frequency signal, an oscillation circuit 112 that generates a carrier wave, an amplification circuit 120 that amplifies the high-frequency signal, and a DC bias application circuit 131 that applies a DC bias to the high-frequency signal from the amplification circuit 120 It has. The control unit 100 also includes an amplifier circuit 140 that amplifies the high-frequency signal received from each of the antenna units 200a to 200d, and a demodulation circuit 113 that demodulates the communication signal from the high-frequency signal. Furthermore, the control unit 100 includes a control signal generation unit 151 that generates a control signal for selecting the antenna units 200a to 200d.

  The DC bias application circuit 131 applies a DC bias to the high frequency signal from the amplifier circuit 120. The voltage value of this DC bias is a predetermined value unlike the first embodiment. The DC bias is used as a power source in the antenna units 200a to 200d.

  The control signal generation unit 151 generates and transmits a control signal for antenna selection based on the selection instruction of the antenna units 200a to 200d from the tag communication control unit 102. The antenna selection control signal is a digital signal corresponding to each of the antenna units 200a to 200d. The output signal of the control signal generation unit 151 is transmitted to the antenna units 200a to 200d through the control signal cables 420a to 420d corresponding to the antenna units 200a to 200d.

  As shown in FIG. 13, the matching circuit unit 210 of the antenna unit 200 includes an AC / DC separation circuit 211, a matching circuit 212, a control signal identifying circuit 213 for identifying a control signal, and an impedance for performing constant control of the matching circuit 212. And an adjustment circuit 214. A coaxial cable 400 is directly connected to the matching circuit 212. A control signal cable 420 is directly connected to the control signal identification circuit 213.

  The AC / DC separation circuit 211 separates the signal received from the control unit 100 into a DC component and an AC component. The separated DC component voltage is a bias value applied by the DC bias application circuit 131 of the control unit 100. The separated DC signal is supplied as a power source to the control signal identification circuit 213 and the impedance adjustment circuit 214. On the other hand, the separated AC component is a high-frequency signal output from the amplifier circuit 120 on the transmission side, and the high-frequency signal is input to the matching circuit 212.

  In the RFID tag reader according to the present embodiment, the amount of wiring between the control unit 100 and the antenna unit 200 is increased as compared with the first embodiment, while the circuits of the control unit 100 and the antenna unit 200 are provided. It can be simplified. Other operations and effects are the same as those of the first embodiment.

  In this embodiment, the modification of the first embodiment has been described. However, the same modification can be applied to the RFID tag reading apparatus according to the second embodiment.

  Although the embodiments of the present invention have been described in detail above, the present invention is not limited to these. For example, in each of the embodiments described above, a showcase has been described as an installation destination of a reader, but the present invention is not limited to a use application.

  In each of the above embodiments, only one antenna unit is selected from the plurality of antenna units 200a to 200d. However, a plurality of antenna units may be selected simultaneously. However, in this case, it is necessary to set each antenna unit so that adjacent antenna units are not selected simultaneously.

  In the above embodiment, only one loop antenna 202 is provided in one antenna unit 200, and a plurality of antenna units 200a to 200d are arranged side by side on the product shelf 2, but one antenna unit 200 is provided. A plurality of loop antennas may be provided inside. Such a modification will be described with reference to FIGS. 14 and 15 are top views for explaining the internal structure of the antenna unit. In FIG. 14, a solid line, a dotted line, a one-dot chain line, and a two-dot chain line are used to clarify the arrangement of the loop antennas 202. Similarly, in FIG. 15, in order to clarify the arrangement of the loop antennas 202, solid lines and dotted lines are used.

  For example, the antenna unit 200 shown in FIG. 14 has four groups of loop antennas 202 and matching circuit units 210 arranged in a casing 201. Each loop antenna 202 is arranged in each divided region obtained by dividing the bottom surface of the housing 201 into four in a matrix. Here, at least some of the adjacent loop antennas 202 are arranged so as to overlap each other. The matching circuit unit 210 is the same as that in the above embodiment.

  Further, for example, in the antenna unit 200 shown in FIG. 15, two sets of the loop antenna 202 and the matching circuit unit 210 are arranged in the housing 201. Each loop antenna 202 is disposed in each divided region obtained by dividing the bottom surface of the housing 201 into two in the longitudinal direction. Each loop antenna 202 has a “figure 8” shape in which two loops are formed by twisting the central portion. At this time, the electromagnetic fields formed by the loops are in opposite directions. Further, the two loop antennas 202 are arranged so that at least a part thereof overlaps each other.

  The antenna unit 200 shown in FIG. 14 and FIG. 15 has a stable reading range because the wiring of the loop antenna 202 is also arranged at the center of the housing 201 as compared with the antenna unit 200 shown in FIG. It has the advantage of becoming.

  In the first and second embodiments, as a method for superimposing the control signal, a method of applying a DC bias having a voltage value corresponding to the control signal to the high-frequency circuit is exemplified, but other superposition methods are adopted. Also good. For example, various methods such as a method of stopping amplitude modulation, frequency modulation, and a high-frequency signal for a predetermined period and transmitting a digital signal within the stop period are conceivable.

1 is a configuration diagram of an RFID tag reader according to a first embodiment. Functional block diagram of a control unit according to the first embodiment The top view explaining the internal structure of the antenna unit concerning a 1st embodiment Functional block diagram of the antenna unit according to the first embodiment Functional block diagram of the centralized control device according to the first embodiment The figure explaining the output signal of an amplifier circuit The figure explaining a control signal Diagram explaining transmission signal Functional block diagram of an antenna unit according to the second embodiment Functional block diagram of a control unit according to the third embodiment Functional block diagram of an antenna unit according to the third embodiment Functional block diagram of a control unit according to the fourth embodiment Functional block diagram of an antenna unit according to the fourth embodiment Top view illustrating the internal structure of an antenna unit according to another example Top view illustrating the internal structure of an antenna unit according to another example

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Goods, 11 ... RFID tag, 100 ... Control unit, 102 ... Tag communication control part, 130, 131 ... DC bias application circuit, 150, 151 ... Control signal generation part, 200 ... Antenna unit, 202 ... Loop antenna, 210 DESCRIPTION OF SYMBOLS ... Matching circuit unit 211 ... DC / AC separation circuit 212 ... Matching circuit 213 ... Control signal identification circuit 214 ... Impedance adjustment circuit 215 ... Switch circuit 216 ... Switch control circuit 400 ... Coaxial cable 410, 420 ... Control signal cable

Claims (7)

In an RFID tag reader comprising a plurality of antennas for communication with an RFID tag, a high-frequency circuit for processing a signal for communication with the RFID tag, and a signal line for connecting the antenna and the high-frequency circuit,
Control means for outputting a control signal for antenna selection;
Matching means for impedance matching of the high frequency signal to the antenna;
A matching control means for matching the impedance matching of the high-frequency signal to the antenna selected by the control signal by the control means and controlling the impedance matching of the high-frequency signal to be non-matching for the non-selected antenna;
An RFID tag reader, wherein impedance matching of a high frequency signal is made non-matching with another antenna adjacent to the antenna while impedance matching of the high frequency signal is achieved with respect to one antenna. The RFID tag reader according to claim 1, wherein the matching control unit changes a circuit constant in the matching unit. The RFID tag reader according to claim 1, wherein a pair of matching means and matching control means is provided for each antenna. The RFID tag reader according to claim 1, wherein the number of antennas selected simultaneously from among a plurality of antennas is one. 2. The RFID tag reader according to claim 1, wherein each antenna includes a loop antenna and is disposed so that a part of a loop of one antenna overlaps a part of a loop of an adjacent antenna. Superimposing means for superimposing the control signal on a high-frequency signal output from the high-frequency circuit to the antenna;
Separating means for separating the superimposed signal input from the superimposing means via the signal line into a high-frequency signal and a control signal, supplying the separated high-frequency signal to the matching circuit and supplying the separated control signal to the matching control means; The RFID tag reader according to claim 1, further comprising: The RFID tag reader according to claim 6, wherein a set of the separating unit, the matching unit, and the matching control unit is provided for each antenna.

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