JP4640704B2 - Wireless tag information reading device, tag label making device - Google Patents

Description

  The present invention relates to a wireless tag information reading device for reading information by wireless communication from a wireless tag circuit element capable of wireless communication of information with the outside, and a tag label producing device for creating a wireless tag label provided with the wireless tag circuit element. It is.

RFID (Radio) that reads / writes information in a non-contact manner between a small wireless tag and a reader (reader) / writer (writer)
Frequency Identification) system is known. The RFID circuit element provided in the RFID tag label includes an IC circuit unit that stores predetermined RFID tag information and an antenna that is connected to the IC circuit unit and transmits / receives information, and the RFID tag label is dirty. Even if it is placed in an invisible position, it is possible to access (read / write information) the RFID tag information of the IC circuit section from the interrogator side, such as product management and inspection process Practical use is expected in various fields.

  As one of wireless communication systems using wireless tags that are being used in various fields as described above, there is a wireless tag information reading device that reads information from a plurality of wireless tag circuit elements by wireless communication (for example, Patent Document 1). In this RFID tag information reading device, an inquiry signal is transmitted to a plurality of RFID tag circuit elements, and a response signal is received from each RFID tag circuit element existing within the communication range. Reading of information is performed.

JP-A-11-149530

  In the case of the above-described conventional wireless tag information reading apparatus, there are the following problems.

  That is, for example, a plurality of RFID circuit elements need to read information (hereinafter referred to as a first reading target) that needs to read information at a relatively high frequency, and a reading target that only needs to read information at a relatively low frequency. (Hereinafter referred to as the second reading target), the wireless tag circuit element as the second reading target does not need to read information at a high frequency, but the wireless communication of the above-described prior art. In the tag information reading device, it is necessary to transmit an inquiry signal at a high frequency according to the first reading target, and to read information from the RFID circuit elements of both the first and second reading targets at a high frequency. As a result, useless reading such as reading information at a high frequency with respect to the second reading target, which is sufficient if the information is read at low frequency, is caused, resulting in a decrease in reading efficiency.

  An object of the present invention is to provide a wireless tag information reading device and a tag label producing device capable of reading information efficiently and quickly by an operator.

  In order to achieve the above object, a first invention relates to a wireless tag circuit element and a wireless tag circuit element that are handled in association with an object and store information and a tag-side antenna connected to the IC circuit part. Communication means for transmitting and receiving information by communication, and determination means for determining a communication mode in the communication means based on attribute information of the object or the RFID tag circuit element corresponding thereto.

  In the first invention of this application, information is transmitted and received by wireless communication by the communication means with respect to the RFID tag circuit element handled in association with the object. At this time, the communication mode by the communication unit is determined by the determination unit according to the attribute information of the object and the RFID tag circuit element.

  Thereby, for example, the RFID circuit element of the target object that needs to read information at a relatively high frequency increases the communication frequency, or the communication output is output from the RFID tag circuit element of the target object whose communication distance is relatively small. Number of retries when communication failure occurs for RFID tag circuit elements that are smaller, sharpen directivity for RFID circuit elements that are subject to roughly determined communication directions, or for RFID tag circuit elements that require strict handling It is possible to set various communication modes such as increasing the number of communication modes.

  In this way, by determining the communication mode to the RFID tag circuit element according to the attribute information of the target object or the RFID tag circuit element, information is transmitted in a communication mode corresponding to the nature and characteristics of the target object or the RFID tag circuit element. Can be read. Therefore, it is possible to read information efficiently and quickly and effectively for the operator as compared with the case where information is read in a uniform communication mode with respect to the RFID circuit elements related to all objects.

  According to a second invention, in the first invention, there is provided an acquisition means for acquiring tag identification information of the RFID circuit element corresponding to the attribute information in response to an attribute information specifying signal designating the type of the attribute information. And the said communication means transmits / receives the said information with the communication aspect determined by the said determination means with respect to the said RFID circuit element which acquired the said tag identification information by the said acquisition means.

  When the operator designates desired attribute information, an attribute information specifying signal based on the specified attribute information is generated, and the acquiring unit acquires tag identification information of the RFID circuit element corresponding to the attribute information specifying signal. Then, the communication means transmits / receives information to / from the RFID circuit element using the communication mode determined by the determination means. In this way, the communication mode corresponding to the object or the RFID tag circuit element can be determined simply by designating the attribute information by the operator, and the information can be read in a communication mode suitable for the properties and characteristics of the target object and the RFID tag circuit element.

  According to a third invention, in the second invention, the communication means outputs one of a plurality of types of inquiry signals for accessing the IC circuit unit of the RFID circuit element in accordance with the attribute information specifying signal. Signal generation means for selecting and generating is provided.

  As a result, for example, for a RFID circuit element of an object having a relatively high movement frequency, an ID is designated and a Scroll ID signal, which is a command for obtaining a response to the RFID circuit element, is transmitted and individually read. For a RFID circuit element of an object whose movement frequency is relatively low, a Ping signal, which is a command for requesting a response by designating a part of the ID, is transmitted and a plurality of objects are read at once. Information can be read in an inquiry mode suitable for the properties and characteristics of the RFID circuit element.

  In a fourth aspect based on the third aspect, the signal generating means generates the inquiry signal designating a part of the tag identification information of the RFID circuit element in accordance with the attribute information specifying signal. Features.

  By generating an inquiry signal designating a part of the tag identification information and transmitting it to the RFID circuit element, information can be read from a plurality of RFID circuit elements having the corresponding tag identification information. In particular, when the attribute information of the target object or the RFID circuit element is incorporated in the tag identification information, the tag identification information represents the attribute information, so that communication is automatically performed corresponding to the tag identification information. It becomes possible to determine the mode, which is more convenient.

  According to a fifth invention, in any one of the first to fourth inventions, the determination unit changes the communication mode according to creation history information of a wireless tag including the wireless tag circuit element as the attribute information. It is characterized by determining.

  By determining the communication mode according to the creation history information of the RFID tag provided with the RFID circuit element by the determining means, for example, depending on when the RFID tag was created, with which device, who made it, etc. The communication mode can be switched.

  A sixth invention is characterized in that, in the fifth invention, the determining means determines the communication mode according to a creation time of the wireless tag as the creation history information.

  As a result, for example, if the creation time is relatively new, it is considered that the object is likely to move relatively well, so the communication frequency is increased and the information is read in detail, while the creation time is relatively old. Can increase the communication frequency by assuming that the object does not move so much, and can read information roughly. As a result, it is possible to prevent a useless reading operation in which information is read at a high frequency uniformly with respect to an object that is sufficient at a low frequency.

  According to a seventh invention, in any one of the first to fourth inventions, the determining means determines the communication mode as the attribute information in accordance with type information of the object.

  By determining the communication mode according to the type of the RFID circuit element, the determining means determines whether it is a shared or private property, a document or a consumable item, a dangerous drug or a normal article, etc. The communication mode can be switched.

  According to an eighth invention, in any one of the first to fourth inventions, the determination unit includes, as the attribute information, read history information for the RFID tag information stored in the IC circuit unit of the RFID circuit element. The communication mode is determined accordingly.

  The determining means determines the communication mode according to the reading history information of the IC circuit unit, for example, the total number of times of reading from the RFID tag information reading device, the position information of the reading device of the RFID tag information that has been read, etc. It becomes possible to switch the communication mode according to.

  In a ninth aspect based on the eighth aspect, the determining means determines the number of movements of the object calculated based on the total number of times of reading by the different RFID tag information reading device for the RFID tag information as the reading history information. The communication mode is determined accordingly.

  As a result, for example, if there is a large number of movements of the object based on the total number of readings, it is considered that there is a high possibility of moving relatively well in the future, and the communication frequency is increased and the information is read in detail. For those having a small number of movements, it is possible to assume that the object does not move so much and reduce the communication frequency so that information can be read roughly. As a result, it is possible to prevent a useless reading operation in which information is read at a high frequency uniformly with respect to an object that is sufficient at a low frequency.

  According to a tenth aspect, in the eighth aspect, the determining unit is configured to calculate the object calculated based on position information of a wireless tag information reading device that has read the wireless tag information as the reading history information. The communication mode is determined according to a moving distance.

  As a result, for example, if the moving distance of the object is large, it is considered that there is a high possibility that it will move relatively well in the future, and the communication frequency is increased and information is read finely, while the moving distance of the object is small. In the future, it can be assumed that the object does not move so much, and the frequency of communication is increased so that information can be read roughly. As a result, it is possible to prevent a useless reading operation in which information is read at a high frequency uniformly with respect to an object that is sufficient at a low frequency.

  According to an eleventh aspect of the present invention, in any one of the first to tenth aspects, the determining unit determines, as the communication mode, a communication frequency with the RFID circuit element in the communication unit.

  As a result, it is possible to prevent a useless reading operation such as reading information with a high frequency uniformly with respect to an object which is sufficient with a low frequency.

  In a twelfth aspect based on any one of the first to the tenth aspects, the determining means, as the communication mode, outputs the communication output with the RFID circuit element in the communication means or the number of retries when communication fails. Alternatively, the directivity of a device-side antenna composed of a plurality of antenna elements is determined.

  As a result, for example, information can be read with a large output uniformly for an object that requires a small output with a short communication distance, or information can be read with a wide directivity for an object with a fixed direction. A useless reading operation can be prevented, and an object for which handling is strict and it is necessary to always know the location can be reliably managed by increasing the number of retries.

In order to achieve the above object, according to a thirteenth aspect of the present invention, there is provided an RFID circuit element including an IC circuit portion that is handled in association with an object and stores information, and a tag-side antenna connected to the IC circuit portion. The wireless tag circuit element storage body having the tag medium stored in a continuously supplyable manner is detachably installed, and information is wirelessly communicated between the IC circuit section of the wireless tag circuit element. A communication means for performing transmission / reception, a printing means for printing on the tag medium conveyed from the RFID circuit element housing, a wireless communication by the communication means, and a printing by the printing means And a creation history information generation unit that generates creation history information of the RFID label.

  In the thirteenth invention of this application, when the tag medium is supplied from the RFID circuit element housing body installed in the housing body installation section, the communication means is used for the IC circuit section of the RFID circuit element provided in the tag medium. Information is transmitted and received by wireless communication, and a predetermined printing is performed on the tag medium by a printing unit to create a wireless tag label. At this time, creation history information of the created RFID label is generated by the creation history information generation means. Thereby, when reading with the RFID tag information reading device for the RFID tag circuit element of the created RFID tag label, based on the creation history information, for example, when the RFID tag was created, with which device, It is possible to switch the communication mode at the time of reading depending on who made it. As a result, information can be read in a communication mode corresponding to the properties and characteristics of the object and the RFID circuit element, so that information can be read in a uniform communication mode for the RFID circuit elements related to all objects. Compared with the case of performing information, the information can be read efficiently and quickly and effectively for the operator.

  In a fourteenth aspect based on the thirteenth aspect, the present invention further comprises information output means for outputting the creation history information created by the creation history information generation means to a storage device having a database.

  Thus, using the creation history information output by the information output means and stored and held in the database by the storage device, the communication mode at the time of reading is switched, and the communication mode corresponding to the nature and characteristics of the object and the RFID circuit element Information can be read.

  According to a fifteenth aspect, in the thirteenth aspect, the communication unit writes the creation history information created by the creation history information generation unit into the IC circuit unit via wireless communication.

  Thereby, using the creation history information written in the IC circuit unit, the communication mode at the time of reading can be switched, and the information can be read in the communication mode corresponding to the property and characteristics of the object and the RFID tag circuit element. .

  According to a sixteenth aspect of the invention, in any one of the thirteenth to fifteenth aspects, the creation history information generating unit creates the creation time information of the RFID label as the creation history information.

  As a result, for example, if the creation time is relatively new, it is considered that the object is likely to move relatively well, so the communication frequency is increased and the information is read in detail, while the creation time is relatively old. Can increase the communication frequency by assuming that the object does not move so much, and can read information roughly. As a result, it is possible to prevent a useless reading operation such as reading information with a high frequency uniformly with respect to an object that needs a low frequency.

  According to the present invention, information can be read efficiently and quickly by an operator.

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

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. This embodiment is an example in which the RFID tag information reading apparatus of the present invention is applied to a file management system in a company, for example.

  FIG. 1 is a system configuration diagram showing an overall configuration of a file management system 1 having a wireless tag information reading device of the present embodiment. As shown in FIG. 1, the cabinet C has a two-stage configuration of an upper stage and a lower stage. A plurality of files F1 (objects) are accommodated in the upper stage, and a plurality of files F2 (objects) are accommodated in the lower stage. ing. In the present embodiment, it is assumed that the file F1 accommodated in the upper stage is a file created relatively recently than the file F2 in the lower stage, and is frequently taken out by the employee M. Here, in order to facilitate understanding, the file F1 is stored in the upper stage and the file F2 is stored in the lower stage. However, the files F1 and F2 may be mixed and stored in the upper or lower stage.

Each of the files F1 and F2 is provided with RFID labels T _F1 and T _F2 each having a RFID circuit element To storing information relating to the files. File management system 1 accesses via the antenna 210 to the information for each file F1, the RFID label T _F1 of F2, the plurality provided in T _F2 RFID circuit element To (in this example reads) reader 200 (A wireless tag information reading device) and a server 207 that is connected to the reader 200 via a communication line 206 and includes a database DB.

Above the RFID label T _F1 and the RFID label T _F2 RFID circuit element To provided in the corresponding information acquired object-specific (or a proviso rewritable) which can specify (where file F1, F2 are) identification information As a tag ID. Then, the reader 200 reads the tag ID and makes an inquiry to the server 207 so that the file can be specified. As described above, the file management system 1 periodically reads information from the plurality of files F accommodated in the cabinet C from the reader 200, so that which file F is taken out from the cabinet C and which file F is Whether it is accommodated in the cabinet C can be detected.

FIG. 2 is a diagram illustrating an example of the overall schematic structure of T _F1 among the RFID labels T _F1 and T _F2 . FIG. 2A is a top view of the RFID label T _F1 , and FIG. 2B is a bottom view. It is. In these figures 2 (a) and FIG. 2 (b), the RFID label T _F1, for example the substrate 2 of the substantially sheet-shaped, is disposed on the substrate 2, the IC circuit part 150 Toko of IC circuit for storing information The wireless tag circuit element To is provided with an antenna 151 (tag antenna) connected to the unit 150.

As shown in FIG. 2 (a), the front side of the RFID label T _F1 of the substrate 2 (upper surface), the corresponding print information (in this example, "File 1") has an area S that notation. Note that these regions S may not be characters but may be graphics or symbols, or simple color painting or patterns.

FIG. 3 is a block diagram showing an example of a functional configuration of the RFID circuit element To provided in the RFID labels T _F1 and T _F2 .

  In FIG. 3, the RFID circuit element To transmits and receives signals in a non-contact manner using the antenna 210 (device-side antenna) of the reader 200 and electromagnetic waves such as a short wave band (eg, 13.56 MHz), UHF band, and microwave band. The antenna 151 to be performed and the IC circuit unit 150 connected to the antenna 151 are included.

  The IC circuit unit 150 includes a rectification unit 152 that rectifies the carrier wave received by the antenna 151, and a power source unit 153 that accumulates energy of the carrier wave rectified by the rectification unit 152 and serves as a driving power source for the IC circuit unit 150. A clock extraction unit 154 that extracts a clock signal from the carrier wave received by the antenna 151 and supplies the clock signal to a control unit (described later) 157; a memory unit 155 that functions as an information storage unit that can store a predetermined information signal; A modulation / demodulation unit 156 connected to the antenna 151, and a control unit 157 for controlling the operation of the RFID circuit element To through the rectification unit 152, the clock extraction unit 154, the modulation / demodulation unit 156, and the like. Yes.

  The modem unit 156 demodulates the communication signal received from the antenna 210 of the reader 200 received by the antenna 151 and modulates the carrier wave received by the antenna 151 based on the return signal from the control unit 157. Retransmit as reflected wave.

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

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

  FIG. 4 is a functional block diagram showing detailed functions of the reader 200.

In FIG. 4, the reader 200 includes the antenna 210 that transmits and receives signals to and from the antenna 151 of the plurality of RFID tag circuit elements To provided in the RFID labels T _F1 and T _F2 , and the antenna 210. The IC circuit unit 150 of the RFID circuit element To is accessed via (via reading in this example), and the high frequency circuit 201 that processes the signal read from the RFID circuit element To and the high frequency circuit 201 The reader 200 includes a function of processing signals read from the IC circuit unit 150 of the RFID circuit element To and reading information and generating access information for accessing the IC circuit unit 150 of the RFID circuit element To. An operation unit 2 including a control circuit 202 that controls the overall operation and appropriate buttons, keys, and the like that can be operated by the operator. 3, a network communication unit 204 for communicating with the server 207 via the communication line 206, a first timer 208 that counts a relatively short period T1 (described later), and a relatively long period T2 (described later). A second timer 209.

RFID circuit element To provided in the RFID label T _F1 and the RFID label T _F2 has an antenna 151 connected to the IC circuit part 150 Toko of the IC circuit part 150 for storing each as described above information. The IC circuit unit 150 (specifically, the memory unit 155) stores a tag ID as unique (but may be rewritable) identification information that can identify the corresponding information acquisition object (here, the files F1 and F2). When the control circuit 202 makes an inquiry to the server 207 using the tag ID, various information (file names and the like) related to the object stored in the database DB of the server 207 is stored in the server 207. The file can be specified. The memory unit 155 may directly store file name information and the like instead of the tag ID.

  The data of each file F is input in advance using an appropriate terminal or the like and stored and held in the database DB of the server 207.

  FIG. 5 is a functional block diagram showing a detailed functional configuration of the high-frequency circuit 201.

  In FIG. 5, the high-frequency circuit 201 includes a transmission unit 212 that transmits a signal to each of the plurality of RFID tag circuit elements To via the antenna 210, and a reflected wave from each RFID circuit element To that is received by the antenna 210. The receiving unit 213 and the transmission / reception separator 214 are input.

  The transmission unit 212 includes a crystal resonator 215 that generates a carrier wave for accessing (reading / writing) the RFID tag information of the IC circuit unit 150 of the RFID circuit element To, a PLL (Phase Locked Loop) 230, and a VCO. (Voltage Controlled Oscillator) 231 and the carrier wave generated by the carrier wave generator based on the signal supplied from the control circuit 202 (in this example, amplitude modulation based on the “TX_ASK” signal from the control circuit 202) Transmission multiplier circuit 216 (in the case of amplitude modulation of the carrier wave, an amplification factor variable amplifier or the like may be used), and the modulated wave modulated by the transmission multiplier circuit 216 is amplified (in this example, “ And a variable transmission amplifier 217 that performs amplification determined by the “TX_PWR” signal. The carrier wave generated by the carrier wave generation unit uses, for example, an electromagnetic wave in a short wave band (13.56 MHz, etc.), a UHF band, a microwave band, etc., and the output of the transmission amplifier 217 passes through the transmission / reception separator 214. The signal is transmitted to the antenna 210 and supplied to the IC circuit unit 150 of each RFID circuit element To. Note that the RFID tag information transmitted and received is not limited to the signal modulated as described above, but may be only a carrier wave.

  The reception unit 213 multiplies the reflected wave from each RFID circuit element To received by the antenna 210 and the generated carrier wave and demodulates the received first multiplication circuit 218, and the reception first multiplication circuit 218 A first bandpass filter 219 for extracting only a signal of a necessary band from the output, a reception first amplifier 221 that amplifies the output of the first bandpass filter 219, and further amplifies the output of the reception first amplifier 221 The first limiter 220 that converts the signal into a digital signal, the reflected wave from each RFID circuit element To received by the antenna 210, and the carrier wave whose phase is delayed by 90 ° by the phase shifter 227 after being generated. Receiving second multiplier circuit 222 for multiplying, and a second bandpass filter for extracting only a signal of a necessary band from the output of the received second multiplier circuit 222 223, a reception second amplifier 225 that amplifies the output of the second band pass filter 223, and a second limiter 224 that amplifies the output of the reception second amplifier 225 and converts it into a digital signal. The signal “RXS-I” output from the first limiter 220 and the signal “RXS-Q” output from the second limiter 224 are input to the control circuit 202 and processed.

  The outputs of the reception first amplifier 221 and the reception second amplifier 225 are also input to an RSSI (Received Signal Strength Indicator) circuit 226 serving as an intensity detection means, and a signal “RSSI” indicating the intensity of these signals is used as a control circuit. 202 is input. Thus, in this example, the reader 200 demodulates the reflected wave from each RFID circuit element To by IQ orthogonal demodulation.

  The control circuit 202 outputs an amplification control signal and a modulation control signal to the high-frequency circuit transmission unit 212, and after receiving a reception signal from the high-frequency circuit reception unit 213, is read from each RFID circuit element To. A predetermined calculation process for processing the signal is performed.

  FIG. 6 is a functional block diagram showing detailed functions of the control circuit 202.

  In FIG. 6, a control circuit 202 is a so-called microcomputer, and includes a CPU 202A, a ROM 202B, a RAM 202C that are central processing units, a circuit control unit 202D that performs signal transmission / reception with the high-frequency circuit 201, and the like, and a temporary storage function of the RAM 202C. The signal processing is performed in accordance with a program stored in advance in the ROM 202B while using.

  The control circuit 202 having the above configuration is connected to the network communication unit 204, the first and second timers 208 and 209, and the high-frequency circuit 201 (antenna 210) described above.

  In the above configuration, the present embodiment is characterized in that a plurality of files to be read information are grouped according to the frequency of use, and the information reading frequency is changed for each group.

  FIG. 7 is a flowchart showing a control procedure executed by the control circuit 202.

  First, in step S <b> 10, a start signal is output to the first timer 208 to start the first timer 208.

  In step S20, a start signal is output to the second timer 209 to start the second timer 209.

  In step S30, it is determined whether the count value of the first timer 208 started in step S10 is greater than a threshold value T1. This threshold value T1 is a threshold value which will be described later in order to set the frequency of reading information from the RFID circuit element To (the RFID circuit element To in the tag list 1) provided in the relatively frequently used file F1. The value is set to a value smaller than the value T2, and is stored in advance in the RAM 202C of the control circuit 202, for example. If the count value of the first timer 208 is greater than the threshold value T1, the determination is satisfied and the routine goes to the next Step S40.

In step S40, the tag list 1 (see FIG. 9 described later) is acquired from the database DB of the server 207 via the network communication unit 204 and the communication line 206. The tag list 1, the tag label producing apparatus (described later) by each of the RFID labels T _F which is registered in the database DB of the tag label production is generated in device server 207 when an RFID label T _F provided in each file F ( This is a list extracted under a predetermined condition from a list of creation history of the RFID tag circuit element To). In the present embodiment, the tag list 1 above in the list of each file F RFID circuit element To provided in the entire RFID label T _F provided, newer wireless tag circuit element creation date is after the predetermined time To is extracted in the tag list 1. That is extracted RFID circuit element To of the RFID label T _F1 provided in the file F1 that has been created relatively recently as described above as a tag list 1. This extraction procedure is performed by a CPU (not shown) included in the server 207, for example.

At step S50, it performs a reading process for reading information from the RFID circuit element To of the total RFID label T _F1 that is described in the tag list 1 obtained at Step S40.

  In the next step S60, a control signal is output to the first timer 208 to reset the count value of the first timer 208. Then, it returns to previous step S30.

  If the count value of the first timer 208 is equal to or less than the threshold value T1 in the previous step S30, the determination is not satisfied and the process proceeds to the next step S70.

  In step S70, it is determined whether or not the count value of the second timer 209 started in step S20 is greater than the threshold value T2. This threshold value T2 is used to set the frequency at which information is read from the RFID circuit element To (the RFID circuit element To in the tag list 2) provided in the relatively infrequently used file F2. The value is set to a value larger than T1, and is stored in advance in the RAM 202C of the control circuit 202, for example. If the count value of the second timer 209 is greater than the threshold value T2, the determination is satisfied and the routine goes to the next Step S80.

In step S80, the tag list 2 (see FIG. 9 described later) is acquired from the database DB of the server 207 via the network communication unit 204 and the communication line 206. The tag list 2, similarly to the tag list 1, the tag label producing apparatus (described later) by registered in the database DB of the server 207 is generated in the tag label producing apparatus when an RFID label T _F provided in each file F This is a list extracted under a predetermined condition from the list of creation histories of each RFID label _TF (RF tag circuit element To). In the present embodiment, the tag list 2, the in the list of each file F RFID circuit element To provided in the entire RFID label T _F provided, older wireless tag circuit creation date is before the predetermined time The element To is extracted in the tag list 2. That is, the wireless tag circuit element To of the RFID label T _F2 provided in file F2 created before relatively as described above is extracted as a tag list 2. This extraction procedure is performed by a CPU (not shown) included in the server 207, for example.

In step S90, it performs a reading process for reading information from the RFID circuit element To of the total RFID label T _F2 listed in the tag list 2 obtained at Step S80.

  In the next step S100, a control signal is output to the second timer 209 to reset the count value of the second timer 209. Then, it returns to previous step S30.

  FIG. 8 is a flowchart showing the detailed procedure of step S50 (or step S90, hereinafter corresponding relationship is the same).

  First, in step S210, the head ID of the tag list 1 (or tag list 2) acquired in step S40 (or step S80) is selected.

In the next step S220, information is read by designating an ID for the RFID circuit element To having the ID selected in step S210. Specifically, an inquiry signal (for example, a specific search signal Scroll ID) for specifying a specific tag and acquiring the related information (corresponding file information) is generated and within the communication range via the high-frequency circuit 201 (in this example the RFID circuit element to provided to the tag label T _F of the entire file F in the cabinet C) present the RFID circuit element to is sent to, and a reply is prompted.

  In the next step S230, whether or not reading of information is completed for the RFID circuit element To having the last ID in the acquired tag list 1 (or tag list 2), in other words, in the tag list 1 (or tag list 2). It is determined whether or not reading of information has been completed for all RFID circuit elements To. If reading of information has not been completed up to the RFID circuit element To associated with the last ID in the tag list 1 (or tag list 2), the determination is not satisfied and the process proceeds to the next step S240, where the tag list 1 ( Alternatively, the next ID in the tag list 2) is selected. Then, the process returns to step S220. On the other hand, if the reading of information for all the RFID circuit elements To in the tag list 1 (or tag list 2) has been completed, the determination is satisfied and this flow ends.

By the flow shown in FIGS. 7 and 8 above is performed, the RFID label T _F1 described in the tag list 1 RFID circuit element To short period T1 for (i.e. at a high frequency) reading line information We, the wireless tag circuit element to of the RFID label T _F2 described in the tag list 2 is a relatively long period T2 (i.e. less frequently) reading of information.

  The case where the tag lists 1 and 2 are determined in advance in the database DB of the server 207 has been described as an example. However, the present invention is not limited to this. For example, the tag list is selected by the control circuit 202 of the reader 200 (FIG. 7). In the middle step S40 and step S80), the tag list may be updated every time. For example, when a tag of a file within one month from the creation date is grouped into the tag list 1 and a tag of a file that has passed one month from the creation date is grouped into the tag list 2, the tag list needs to be updated every day. In such a case, before selecting the tag list in steps S40 and S80 in FIG. 7, the tag list registered in the database DB is read once from the server 207, and the tag list is updated based on the creation date information. It is sufficient to rewrite the list on the database DB and select the tag list on it. In this way, the communication frequency can always be determined using the latest attribute information (tag list).

  In the above, when reading information from each RFID circuit element To, a specific tag is specified and an inquiry signal (specific search signal Scroll ID) for acquiring information is transmitted. However, the present invention is not limited to this, and an inquiry signal command may be determined according to the attribute of the object. For example, the specific search signal Scroll ID is transmitted to the RFID circuit element To in the tag list 1 in step S50, and the unspecified search signal Ping is transmitted to the RFID circuit element To in the tag list 2 in step S90. May be transmitted to read the information. As a result, the RFID circuit element To of the file 1 having a relatively high movement frequency is transmitted by individually transmitting a Scroll ID signal, and the RFID circuit element To of the file 2 having a relatively low movement frequency. In response to this, a Ping signal can be transmitted and a plurality of portions can be read at a time, and the reading efficiency can be further improved.

  FIG. 9 is a conceptual diagram showing an example of the creation history list, tag list 1 and tag list 2 of each RFID circuit element To registered in the database DB of the server 207.

A tag label producing device (described later) is connected to the database DB of the server 207 via, for example, a network, and each wireless tag generated when the RFID label _TF provided in each file F is produced by the tag label producing device. The creation history information of the tag label T _F (RFID tag circuit element To) is registered as a list. In FIG. 9, the creation history information includes an ID for each RFID circuit element To, information relating to an object (file name in this case), creation date and time, and three RFID circuit elements To and files provided in the file F1. The creation history information of the above items is registered as a list for each of the four RFID circuit elements To provided in F2.

  For example, the registered list is grouped under a predetermined condition by a CPU (not shown) of the server 207. In this embodiment, as shown in the figure, a tag with the latest creation date (created after October 2005) is extracted as the tag list 1 and the creation date is old (created before September 2005). Tag list 2 is extracted.

In this embodiment, as described above, the communication frequency is determined using the creation date and time as the creation history information. However, the present invention is not limited to this. For example, which creation of each RFID label T _F (RF tag circuit element To) The creation history information may include information such as whether it was made by the device, which cartridge it was made, the color, shape, printed information of the created tag label, or who made it. By determining the communication frequency according to such creation history information, the communication frequency can be determined more finely according to the attributes of the object.

The RFID label labels T _F1 and T _F2 configured and used as described above. As a label producing apparatus 300 (tag label producing apparatus) for manufacturing these RFID label labels T _F1 and T _F2 , for example, an apparatus shown in FIG. Used.

In FIG. 10, this tag label producing device 300 (wireless tag information writing device) includes a tag tape roll 304 (wireless tag circuit element) wound around a tag tape 303 (tag medium) provided with a wireless tag circuit element To at a predetermined interval. A tag tape roll holder unit 310 (container installation unit) that can be attached and detached (or a cartridge that includes a tag tape roll 304), and a tag tape 303 that is fed out from the tag tape roll 304 A print head 305 (printing means) that performs predetermined printing on the region S corresponding to the RFID circuit element To and an antenna 306 (communication means) that transmits and receives information between the RFID circuit element To by wireless communication. A high-frequency circuit 301 (communication means) and a control circuit 302 (creation history information generation means); Shaped and the RFID circuit element above information writing is to cut the tag tape 303 has been completed to a predetermined length RFID label T (= the T _F1, T _F2, etc.) to the To a cutter 307 to, the print head 305 And a conveying device 309 that is provided oppositely and is controlled by the control circuit 302 to convey the tag tape roll 304.

Although the detailed description of the high-frequency circuit 301 and the control circuit 302 is omitted, the high-frequency circuit 301 and the control circuit 302 have substantially the same functions as the high-frequency circuit 201 and the control circuit 202 of the reader 200, and the IC circuit unit 150 of the RFID circuit element To. Is transmitted to the RFID circuit element To via the device-side antenna 306, and information is written to the IC circuit unit 150 of the RFID circuit element To. The control circuit 302 is connected to the server 207, other computers, terminals, and the like via the wired or wireless communication line (network) 206, and information can be transmitted / received to / from them. Accordingly, the RFID label T (= the T _F1, T _F2, etc.) to create history information transmitted to the database DB of the server 207, which is to be registered.

  FIG. 11 is a flowchart showing a control procedure executed by the control circuit 302 when the RFID label T is created.

  In FIG. 11, first, in step S710, a print that is separately input by an operation terminal (connected to the control circuit 302 via the communication line 206) or the like to be printed on the area S of the RFID label T by the print head 305. Information and information to be written to the RFID circuit element To are acquired via the communication line 206. In addition, it may replace with the said operation terminal etc. and you may make it input from the operation part which is not shown of the tag label production apparatus 300.

Thereafter, the process proceeds to step S720, and after printing is performed on the RFID circuit element To, the process proceeds to step S725, where the information is conveyed to the tag writing position and the information is written (for example, the tag ID and file information to be stored). Then, an RFID label T comprising a single RFID circuit element To perform tape cutting (= the T _F1, T _F2, etc.) in step S730.

  Thereafter, in the next step S740, the creation history information including the tag ID of the RFID circuit element To provided in the created tag label T, the written file information (file name), and the creation date and time is transmitted via the communication line 206. The data is transmitted to the server 207 and registered in the database DB. Then, this flow ends.

  In the above, the high frequency circuit 201 constitutes a signal generating means for selecting and generating one of a plurality of types of inquiry signals according to claim 3, and the high frequency circuit 210 and the antenna 210 are connected to the RFID circuit element To. Communication means for transmitting and receiving information by wireless communication is configured. Further, the control circuit 202 (specifically, step S40 and step S80 in the flow of FIG. 7) constitutes a determination unit that determines a communication mode in the communication unit, and tag identification information of the RFID circuit element corresponding to the attribute information The acquisition means for acquiring is configured.

In the present embodiment configured as described above, the RFID circuit element To that exists within the communication range from the reader 200 every predetermined time (in this example, the tag labels T _F1 , F 1 and F 2 of the files F 1 and F 2 accommodated in the cabinet C). signal inquiry to the wireless tag circuit element to) provided in the T _F2 is transmitted, and a reply is prompted. At this time, the attribute information to be read (in this embodiment, creation date / time information of the RFID circuit element To provided in the files F1 and F2) is registered in advance in the database of the server 207, and the control circuit 202 of the reader 200 is The frequency at which the inquiry signal is transmitted is determined based on the attribute information. That is, in this embodiment, reads a short in the period T1 (i.e. at a high frequency) information for the RFID circuit element To of the RFID label T _F1 described in the tag list 1, which is described in the tag list 2 reading a relatively long in period T2 (i.e. less frequently) information for the RFID circuit element to of the RFID label T _F2.

  As a result, the frequency of communication can be increased with respect to the RFID circuit element To that is a target object that needs to be read at a high frequency, such as the file F1 that is relatively recently created and used frequently. The communication frequency can be lowered with respect to the RFID circuit element To that is an object that needs to be read at a low frequency, such as the file F2 that is created before and has a low frequency of use. Thus, by determining the communication mode (communication frequency in the present embodiment) to the RFID circuit element To according to the attribute information of the target object (creation date and time in the present embodiment), the properties and characteristics of the target object are determined. The information can be read in a communication mode corresponding to the above. Therefore, compared to the case where information is read in a uniform communication mode (here, uniform communication frequency) with respect to the RFID circuit elements To related to all the objects, the object which is sufficient in frequency is uniformly high in frequency. Since it is possible to prevent useless reading operations such as reading information, it is possible to efficiently read information efficiently and quickly for the operator of the file management system 1.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the gist and the technical idea. The modifications will be described below.

(1) When grouping by type of target object In the above embodiment, grouping is performed using the creation date and time of a tag provided on the target object as attribute information of the target object, and the communication frequency is changed according to the group. However, the present invention is not limited to this. For example, grouping may be performed according to the type of the object.

  FIG. 12 is a system configuration diagram showing the overall configuration of a file management system 1A having a wireless tag information reading device in this modification. As shown in FIG. 1, a plurality of files F3 (objects) that are personal items of the employee M1 are placed on the desk of the desk D of the employee M1. On the other hand, the cabinet C accommodates a file F4 (object) shared by a plurality of employees such as the employee M2. Therefore, in the present modification, the file F3 on the desk of the employee M1 is private and therefore is not frequently taken out from the desk D, and the file F4 accommodated in the cabinet C is shared, so the frequency is taken out from the cabinet C. Is high.

Each of the files F3 and F4 is provided with RFID labels T _F3 and T _F4 each having a RFID circuit element To storing information relating to the target file. When these RFID labels T _F3 and T _F4 (RF tag circuit elements To) are created by the tag label producing device, creation history information is created in the same manner as in the above embodiment, and the server 207 is connected via the communication line 206. Registered as a list in the database DB. At this time, the RFID circuit element To provided in the file F4 is extracted as the tag list 1, and the RFID circuit element To provided in the file F3 is extracted as the tag list 2. The other configuration of the file management system 1A is the same as that of the above-described file management system 1, and thus description thereof is omitted.

Or in this modified example is configured as, of the RFID label T _F4 listed in the tag list 1 RFID circuit element To short period T1 for (i.e. at a high frequency) reading of information is performed, the tag relatively long in period T2 (i.e. less frequently) reading of information is performed for a radio tag circuit element to of the RFID label T _F3 described in Listing 2.

  As a result, the frequency of communication can be increased with respect to the RFID circuit element To that is an object that needs to be read frequently, such as the file F4 that is used as a shared object and frequently used, and the personal property. As in the case of the file F3 that is used as a low frequency of use, the frequency of communication can be lowered for the RFID circuit element To that is an object that only needs to read information at a low frequency. Therefore, as in the above-described embodiment, information can be read efficiently and quickly and effectively for the operator of the file management system 1A.

  In this modification, the case where the object is a private item and a common item has been described as an example of the kind of the object. However, the present invention is not limited to this. For example, the handling when the consumable item is not a consumable item or the object is a drug is used. It can be applied to objects that have different varieties such as attention powerful drugs or normal drugs.

(2) When writing attribute information in a tag In the above embodiment, the creation date and time as the attribute information of the object is registered in the database DB of the server 207. However, the present invention is not limited to this. In the tag ID to be written to each RFID circuit element To when creating T, the attribute of the object may be represented by a part of the ID (for example, several digits at the head).

  In the case of this modification, for example, if the first 4 bits of the ID are 1111, the tag belongs to the tag list 1, and if the first 4 bits of the ID is 1110, the tag belongs to the tag list 2. When the RFID label T is created at 300, the ID starting from the 4 bits is written according to the creation date. When reading information with the reader 200, for the reading performed in the T1 cycle, an inquiry signal (for example, a specific tag) specifying an unspecified tag in which the first 4 bits of the ID are 1111 and the subsequent bits are arbitrary. The search signal Scroll ID) is transmitted to the RFID circuit element To within the communication range. On the other hand, for reading performed in the T2 cycle, an inquiry signal (for example, a specific search signal Scroll ID) designating an unspecified tag in which the first 4 bits of the ID are 1110 and the subsequent bits are optional is wireless within the communication range. It is sufficient to transmit to the tag circuit element To.

  When the attribute information of the object is incorporated in the ID information written in the RFID circuit element To as in the present modification, the tag ID represents the attribute information. It is not necessary to register the creation history information as attribute information in the database DB of the server 207. Therefore, the database DB becomes unnecessary.

  In the above description, the first 4 bits of the ID are specified, and the subsequent bits are arbitrary. The information is read by an inquiry signal specifying an unspecified tag (for example, a specific search signal Scroll ID). Not limited to this, all RFID circuit elements To in the communication range are inquired by an inquiry signal (for example, unspecified search signal Ping) for an unspecified tag for which no ID is specified, and attribute information is obtained from a part of the read ID. And the communication mode may be automatically determined.

(3) When specifying an attribute condition In the above embodiment, the communication frequency is determined using the tag lists 1 and 2 registered in advance in the database DB of the server 207. However, the present invention is not limited to this. The operator may be able to specify attributes (in this case, specification input of a tag list).

  In this modification, when an operator inputs a tag list using the operation unit 203 of the reader 200, the control circuit 202 uses the network input unit 204 and the network communication unit 204 based on the specified input signal (attribute information specifying signal). The tag list on the database DB of the server 207 is rewritten via the communication line 206.

  Thereby, for example, in the above embodiment, the file F2 is classified because the creation time is old. However, when there is a file whose contents are important and frequently used, the RFID circuit provided in the file F2 is used. The ID of the element To can be rewritten to the tag list 1. As a result, with respect to the file F2, information is read with high frequency at a short period T1 together with the file F1. As described above, according to the present modification, the attributes of the object can be set more finely according to the situation and the like, so that information can be read more efficiently and quickly. .

  In the above, the designation input of the attribute of the object is performed using the operation unit 203 of the reader 200. However, the present invention is not limited to this. For example, input from another appropriate terminal connected to the communication line 206 is performed. The list on the database DB of the server 207 may be rewritten.

(4) Other attribute information variations (i) When the number of times the object is moved is used as attribute information In the above embodiment, the creation history information of the RFID label T provided on the object is used as the attribute information of the object. However, the present invention is not limited to this. For example, the total number of movements of the object may be used as attribute information, and the communication frequency may be determined according to the attribute information.

FIG. 13 is a system configuration diagram showing the overall configuration of the file management system 1B in the present modification. As shown in FIG. 13, cabinets C1, C2 and C3 contain a plurality of files F (objects) each provided with a RFID label _TF provided with a RFID circuit element To.

File management system. 1B, the cabinet C1, C2, C3 each file F of the RFID label T wireless tag included in _F circuit element To of the information to the antenna 210A to be accommodated respectively, 210B, accessed through 210C (this The reader 200A, 200B, 200C (wireless tag information reading device), which is read in the example), and a server 207 ′ having a database DB connected to the reader 200A, 200B, 200C via the communication line 206 are provided. Yes.

  In the file management system 1B configured as described above, information is read from each file F accommodated in the cabinets C1, C2, and C3 periodically by the readers 200A, 200B, and 200C, so that which file F is in which cabinet C. It is possible to manage which cabinet C is taken out.

  In this modification, read history information (the total number of movements in this modification) of each RFID circuit element To is based on information input from each reader 200A, 200B, 200C by a CPU (not shown) of the server 207 ′. They are created, listed, and registered in the database DB. The number of movements is counted as one time when reading is performed by a different reader. For example, the file F read in the cabinet C1 (that is, by the reader 200A) is the cabinet C2 or the next time. When reading is performed at C3 (that is, by the reader 200B or 200C), it is counted as one time. However, when the file F read at the cabinet C1 is next read at the same cabinet C1. Is not counted.

  FIG. 14 is a conceptual diagram showing an example of the read history list, tag list 1 and tag list 2 of each RFID circuit element To registered in the database DB of the server 207 ′ in this modification.

  As shown in FIG. 14, the reading history information includes an ID for each RFID circuit element To, information related to an object (here, a file name), and the number of movements. The reading of the above items is performed for each RFID circuit element To. Each piece of history information is registered as a list. For example, the registered list is grouped under a predetermined condition by a CPU (not shown) of the server 207 ′. In the present embodiment, as shown in the figure, a tag list 1 is extracted by extracting a relatively large number of movements (here, for example, five or more), and a relatively small number of movements (for example, four times here). The following is extracted as a tag list 2.

  The procedure for reading information from each RFID circuit element To performed by each reader 200A, 200B, 200C is the same as that in FIGS.

  According to the above-described modification, regarding a file having a large number of movements of the file F based on the total number of times of reading, it is considered that there is a high possibility that the file F will move relatively in the future, and the communication frequency is increased, so that detailed information is obtained. On the other hand, if the number of movements of the file F based on the total number of readings is small, the object can be regarded as not moving so much and the communication frequency can be lowered to roughly read the information. As a result, it is possible to prevent a useless reading operation such as reading information with a high frequency evenly for a target that is sufficient in a low frequency. The same effect that an effective information can be read is obtained.

(Ii) When the moving distance of the object is used as attribute information In the above embodiment, the creation history information of the RFID label T provided on the object is used as the attribute information of the object. The moving distance of the object may be used as attribute information, and the communication frequency may be determined accordingly.

  In the file management system according to the present modification, the read history information of each RFID circuit element To (based on the movement distance in this modification) based on information input from the readers 200A, 200B, and 200C by a CPU (not shown) of the server 207 ′. ) Are created, listed, and registered in the database DB. This movement distance is the detection of the movement distance when the information is read from each RFID circuit element To by each reader compared to the position where the RFID circuit element To was read before. The total travel distance (total travel distance). The distances between the cabinets C1, C2, and C3 are registered in advance in the database DB. Therefore, for example, when the file F read in the cabinet C1 (that is, by the reader 200A) is next read in the cabinet C2 or C3 (that is, by the reader 200B or 200C), the corresponding movement distances are respectively set. However, when the file F read in the cabinet C1 is read again in the same cabinet C1, the movement distance is set to zero. Other functions and configurations are the same as those of the file management system 1B shown in FIG.

  FIG. 15 is a conceptual diagram showing an example of the read history list, tag list 1 and tag list 2 of each RFID circuit element To registered in the database DB of the server 207 ′ in this modification.

  As shown in FIG. 15, the reading history information includes an ID for each RFID circuit element To, information on an object (here, a file name), and a moving distance. The reading of the above items is performed for each RFID circuit element To. Each piece of history information is registered as a list. For example, the registered list is grouped under a predetermined condition by a CPU (not shown) of the server 207 ′. In the present embodiment, as shown in the drawing, a tag list 1 is extracted by extracting a relatively long moving distance (here, for example, 25 m or more), and a relatively small number of movements (here, for example, 20 m or less). Stuff) is extracted as tag list 2.

  According to this modification described above, regarding the file F having a large moving distance, it is considered that there is a high possibility that the file F will move relatively well in the future, the communication frequency is increased, information is read finely, while the moving distance is small. As for the file F, it can be assumed that the object does not move much in the future, and the communication frequency is increased so that information can be read roughly. As a result, it is possible to prevent a useless reading operation such as reading information with a high frequency evenly for a target that is sufficient in a low frequency. The same effect that an effective information can be read is obtained.

(5) Variation of communication mode In the above embodiment, the communication frequency is determined according to the attribute of the object, but the communication mode to be determined is not limited to this. That is, for example, as another communication mode, the communication output with the RFID circuit element To in the reader 200 (high-frequency circuit 201), the number of retries at the time of communication failure, or the antenna 210 of the reader 200 includes a plurality of antenna elements. In the case of comprising, the directivity of the antenna may be determined.

  As a result, for example, it is unnecessary to read information with a large output uniformly for an object that requires a small output with a short communication distance, or to read information with a wide directivity for an object with a fixed direction. In addition, it is possible to prevent an unintentional reading operation, and it is possible to reliably perform management by increasing the number of retries for an object that is strictly handled and needs to always know the location.

  In the above, an example in which the present invention is applied to a file management system that reads and manages file information in a company has been described. However, the present invention is not limited to this, for example, a system that reads information on a person and the property of the person, etc. The present invention can be applied to a system that reads information from an object composed of a plurality of groups that preferably change communication modes when reading information.

  Further, it is assumed that the “Scroll ID” signal, the “Ping” signal, and the like used above conform to the specifications established by EPC global. EPC global is a non-profit corporation established jointly by the International EAN Association, which is an international organization of distribution codes, and the United Code Code Council (UCC), which is an American distribution code organization. Note that signals conforming to other standards may be used as long as they perform the same function.

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

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

1 is a system configuration diagram showing an overall configuration of a file management system having an embodiment of a wireless tag information reading device of the present invention. It is the upper side figure and bottom view showing an example of the whole schematic structure of a radio | wireless tag label. It is a block diagram showing an example of a functional structure of the RFID circuit element with which the RFID tag label was equipped. It is a functional block diagram showing the detailed function of the reader which is one Embodiment of the RFID tag information reading apparatus of this invention. It is a functional block diagram showing the detailed functional structure of a high frequency circuit. It is a functional block diagram showing the detailed function of a control circuit. It is a flowchart showing the control procedure which a control circuit performs. It is a flowchart showing the detailed procedure of the tag reading process shown in the flow of FIG. It is a conceptual diagram showing an example of a creation history list, a tag list, and a tag list of each RFID circuit element registered in a server database. It is a conceptual diagram showing the structure of the tag label production apparatus by one Embodiment of this invention. It is a flowchart showing the control procedure performed by the control circuit of a tag label production apparatus at the time of creation of a wireless tag label. It is a system configuration | structure figure which shows the whole structure of the file management system in the modification in the case of grouping with the kind of target object. It is a system configuration | structure figure which shows the whole structure of the file management system in the modification in case reading history information is made into attribute information. FIG. 10 is a conceptual diagram illustrating an example of a list of reading histories and tag lists of each RFID circuit element registered in a database of a server in a modification example in which the number of movements of an object is attribute information. FIG. 11 is a conceptual diagram illustrating an example of a list of reading histories and tag lists of each RFID circuit element registered in a database of a server in a modification in which the moving distance of an object is attribute information.

Explanation of symbols

150 IC circuit section 151 antenna (tag side antenna)
200 reader (wireless tag information reader)
200A reader (wireless tag information reader)
200B reader (wireless tag information reader)
200C reader (wireless tag information reader)
201 High-frequency circuit (communication means, signal generation means)
202 Control circuit (determination means, acquisition means)
210 Antenna (communication means)
300 Tag Label Making Device 301 High Frequency Circuit (Communication Means)
302 Control circuit (creation history information generation means)
303 Tag tape (tag medium)
304 Tag tape roll (wireless tag circuit element housing)
305 Print head (printing means)
306 Antenna (communication means)
310 Tag tape roll holder part (container installation part)
DB database F file (object)
F1, F2 file (object)
F3, F4 file (object)
To RFID tag circuit element

Claims (16)

A communication means for transmitting and receiving information by wireless communication with an RFID circuit element including an IC circuit unit that is handled in association with an object and stores information, and a tag-side antenna connected to the IC circuit unit;
An RFID tag information reading apparatus comprising: a determination unit that determines a communication mode in the communication unit based on attribute information of the object or the RFID circuit element corresponding to the object. The wireless tag information reading device according to claim 1,
In accordance with an attribute information specifying signal that specifies the type of the attribute information, an acquisition unit that acquires tag identification information of the RFID circuit element corresponding to the attribute information,
The wireless tag information reading apparatus, wherein the communication unit transmits and receives the information to and from the RFID circuit element that has acquired the tag identification information by the acquisition unit, according to the communication mode determined by the determination unit. The wireless tag information reader according to claim 2,
The communication means includes
A wireless tag comprising signal generation means for selecting and generating one of a plurality of types of inquiry signals for accessing the IC circuit portion of the RFID circuit element in accordance with the attribute information specifying signal Information reader. The wireless tag information reading device according to claim 3,
The signal generating means includes
The wireless tag information reading device, wherein the inquiry signal specifying a part of the tag identification information of the RFID circuit element is generated according to the attribute information specifying signal. The wireless tag information reading device according to any one of claims 1 to 4,
The wireless tag information reading apparatus, wherein the determining means determines the communication mode according to creation history information of a wireless tag including the wireless tag circuit element as the attribute information. The wireless tag information reading device according to claim 5,
The wireless tag information reading device, wherein the determining means determines the communication mode according to a creation time of the wireless tag as the creation history information. The wireless tag information reading device according to any one of claims 1 to 4,
The wireless tag information reading apparatus, wherein the determining means determines the communication mode according to the type information of the object as the attribute information. The wireless tag information reading device according to any one of claims 1 to 4,
The determination unit determines the communication mode according to reading history information for the RFID tag information stored in the IC circuit unit of the RFID circuit element as the attribute information. apparatus. The wireless tag information reader according to claim 8,
The determining means determines the communication mode according to the number of movements of the object calculated based on the total number of times of reading by the different RFID tag information readers for the RFID tag information as the reading history information. A wireless tag information reader. The wireless tag information reader according to claim 8,
The determining means determines the communication mode according to a moving distance of the object calculated from position information of a wireless tag information reading device that has read the wireless tag information as the reading history information. A wireless tag information reading device. The wireless tag information reader according to any one of claims 1 to 10,
The apparatus for reading RFID tag information, wherein the determining means determines, as the communication mode, a communication frequency with the RFID circuit element in the communication means. The wireless tag information reader according to any one of claims 1 to 10,
The determining means determines, as the communication mode, communication output with the RFID circuit element in the communication means, the number of retries at the time of communication failure, or directivity of a device side antenna composed of a plurality of antenna elements. A wireless tag information reader characterized by the above. An RFID circuit element including an IC circuit unit that is handled in association with an object and stores information and a tag-side antenna connected to the IC circuit unit is arranged, and has a tag medium that can be continuously supplied. A storage body installation section for detachably installing the wireless tag circuit element storage body;
Communication means for transmitting and receiving information by wireless communication with the IC circuit portion of the RFID circuit element;
Printing means for printing on the tag medium conveyed from the RFID circuit element housing;
A tag label producing apparatus comprising: wireless communication by the communication means; and creation history information generating means for generating creation history information of a RFID label produced by executing printing by the printing means. In the tag label production apparatus according to claim 13,
An apparatus for producing a tag label, comprising: information output means for outputting the creation history information created by the creation history information generation means to a storage device having a database. In the tag label production apparatus according to claim 13,
The tag label creating apparatus, wherein the communication unit writes the creation history information created by the creation history information creation unit into the IC circuit unit via wireless communication. The tag label producing apparatus according to any one of claims 13 to 15,
The creation history information generation means creates the RFID label creation time information as the creation history information.

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