JP5157793B2 - RFID system - Google Patents

Description

  The present invention relates to an RFID system.

  In recent years, RFID (Radio Frequency IDentification) tags that store and hold predetermined identification information are widely used, and RFID systems that manage production, logistics, articles, etc. by attaching these RFID tags to managed articles have been developed. Proposed. The RFID system includes a plurality of RFID tags and a reader / writer that reads identification information of these RFID tags.

In the conventional RFID system, the RFID tag has a reading completion flag, and the RFID tag whose identification information has been read by the reader / writer sets the reading completion flag so that it does not respond to subsequent reading commands. . Thus, the reader / writer performs the reading process until there is no response from the RFID tag, and reads the identification information of all the RFID tags in the communication area (for example, see Patent Document 1).
JP 2006-233831 A

  In the conventional RFID system, since the read completion flag of the RFID tag is undecided in the initial state, the reader / writer issues an initialization command to determine the read completion flag for the RFID tag existing in the communication area. It was outgoing. However, when the RFID tag is attached to a moving managed article and a new RFID tag is added to the communication area, reinitialization is required. When this re-initialization is performed, the reading completion flag is also initialized, so that RFID tags that have already been read are also read again. For this reason, there has been a problem that the reading efficiency is lowered.

Therefore, the present invention does not duplicately read RFID tags that have already been read by a reader / writer installed in another location, and only initializes the new RFID tag read completion flag again. The identification information can be read, and the purpose is to suppress a decrease in reading efficiency.

RFID system of the present invention includes a plurality of RFID tags holds storing identification information, and the reader-writer for reading the identification information from each of a plurality of RFID tags, and each of the plurality of RFID tags in order to achieve this object, A read completion flag that holds information indicating whether or not reading of identification information has been completed, an auxiliary flag that holds information whether or not the read completion flag has been initialized, and a control unit that operates the read completion flag or auxiliary flag When have, interrogator, an auxiliary reset command transmitting unit which transmits an auxiliary reset command for initializing based read completion flag information of the auxiliary flag for a plurality of RFID tags, a plurality of RFID tags When the auxiliary flag is information indicating non-initialization, each control unit sends an auxiliary reset command sent by the reader / writer. Thus, the read completion flag is initialized to read incomplete, the auxiliary flag is manipulated to information indicating initialization, and after initialization, the identification information is read by the reader / writer in the state after initialization. By setting the completion flag to read completion and using the auxiliary reset command sent by the reader / writer, the read completion flag is not initialized to read uncompleted, and subsequent read commands sent from the reader / writer are not In response to the response, the auxiliary flag is switched to information indicating non-initialization when a predetermined time elapses after the information indicating initialization is operated . With such a configuration, the initial purpose is achieved.

Or RFID system of the present invention as described has a plurality of RFID tags holds storing identification information, and a reader-writer for reading the identification information from each of a plurality of RFID tags, each of the plurality of RFID tags, identification information A read completion flag for holding information indicating whether or not reading has been completed, an auxiliary flag for holding information about whether or not the read completion flag has been initialized, and a control unit for operating the read completion flag or the auxiliary flag , The reader / writer has an auxiliary reset command transmission unit that transmits an auxiliary reset command for initializing a reading completion flag based on information of the auxiliary flag to a plurality of RFID tags, and controls each of the plurality of RFID tags. When the auxiliary flag is information indicating non-initialization, the reading is performed by an auxiliary reset command transmitted by the reader / writer. The read completion flag is initialized to read incomplete, the auxiliary flag is manipulated to information indicating initialization, and after initialization, the identification information is read by the reader / writer in the state after initialization. Is set to read complete, and the read reset flag sent by the reader / writer is not initialized by using the auxiliary reset command sent by the reader / writer. The auxiliary flag is controlled and a predetermined time has passed since the operation was performed on the information indicating initialization.
Since it is configured to switch to information indicating non-initialization, it is possible to initialize only the read completion flag of the RFID tag that has not been initialized by using the auxiliary reset command. For this reason, RFID tags that have already been read by reader / writers installed in other locations are not duplicated, and only the new RFID tag read completion flag is initialized again to identify information. , And RFID tags that have already been read are not read twice. Thereby, a decrease in reading efficiency can be suppressed.

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

(Embodiment)
First, the overall configuration and operation of the RFID system 1 according to the embodiment of the present invention will be described with reference to FIG.

  FIG. 1 is a schematic diagram of an RFID system 1 according to an embodiment of the present invention. Here, as the managed article 4, for example, a product stored and managed in a warehouse will be described as an example. In the warehouse, a large number of managed articles 4 are loaded on a pallet or the like from an unspecified location and are carried by a forklift. In addition, since a large number of managed articles 4 are shipped to unspecified places, management becomes very complicated.

  Therefore, in the present embodiment, as shown in FIG. 1, RFID tags 2 a to 2 i are attached to the respective managed articles 4, and are managed by the RFID system 1 by being read by the reader / writer 3.

  As described above, the RFID system 1 includes the RFID tags 2 a to 2 i and the reader / writer 3. In order to facilitate understanding in the following description, a plurality of RFID tags 2a, 2b, 2c, 2d, 2e, 2f, 2g, 2h, 2i,. In the present embodiment, the number of RFID tags 2 is described as nine, but the number is not limited to this.

  The RFID tag 2 attached to each managed article 4 stores identification information for each managed article 4 (for example, product name, product number, manufacturing date, shipping date, etc.). "Where is the product number B of A?" Is managed.

  The reader / writer 3 shown in FIG. 1 performs the management. The reader / writer 3 communicates with the RFID tag 2 through the transmission / reception unit 31 and the antenna 3a, and is stored and held in the tag circuit unit 20b of the RFID tag 2. The identification information 25b is read and managed via the tag antenna unit 20a. Note that the reader / writer 3 may be used by being connected to a management device (not shown) installed at another location. Thereby, the management article 4 can be managed efficiently in large quantities.

  Next, the RFID tag 2 includes a tag antenna unit 20a and a tag circuit unit 20b that communicates with the reader / writer 3 via the tag antenna unit 20a. The tag circuit unit 20b includes a transmission / reception unit 21, a section allocation unit 22, and a random number. A generation unit 23, an auxiliary flag 24, a memory unit 25, and a control unit 26 are included.

  The transmission / reception unit 21 receives a question signal (various commands) from the reader / writer 3 and returns a response signal. Thereby, various commands (for example, reset command for initialization, auxiliary reset command, read command), identification information 25b, and the like are transmitted and received.

  The division assigning unit 22 time-divides the communication time based on a predetermined value called a Q value (a value specifying the number of time slots), which will be described later, received from the reader / writer 3 via the tag antenna unit 20a and the transmitting / receiving unit 21. Any one of the plurality of time slots is assigned to the own device. For example, when there are eight time slots, one of “0” to “7” is assigned to the own device based on the value of the random number generated by the random number generation unit 23 described later.

  The random number generation unit 23 generates a random number used when assigning time slots. The random number generator 23 also generates a random number for authentication processing on the reader / writer 3 side.

  The auxiliary flag 24 is a flag that holds the operation information of the reading completion flag 25a for a predetermined time. The setting of the auxiliary flag 24 will be described later.

  The memory unit 25 stores a read completion flag 25a, identification information 25b, random number information 25c, slot counter information 25d, and the like. In the identification information 25b, the identification information of the managed article 4 (for example, product name, product number, manufacturing date, shipping date, etc.) is stored. In the random number information 25c, a random number generated by the random number generation unit 23 is temporarily stored. The slot counter information 25d temporarily stores the number (value) of the time slot assigned to the own device.

  The control unit 26 includes a central processing unit (CPU), a read only memory (ROM) for storing various programs and control programs, and a random access memory (RAM) for temporarily storing data and the like, and controls circuits of the respective units. In the control unit 26, when the identification information 25b is normally read by the reader / writer 3, the reading completion flag 25a is set to read completion. The control unit 26 also sets the auxiliary flag 24 when a reset command and an auxiliary reset command are received from the reader / writer 3 via the tag antenna unit 20a and the transmission / reception unit 21. Further, the control unit 26 sets the auxiliary flag 24 when the reading completion flag 25a is set.

  Next, the reader / writer 3 is configured as follows in order to read the identification information 25b from the RFID tag 2 described above.

  That is, the reader / writer 3 includes a transmission / reception unit 31, a section number designation unit 32, a collision number acquisition unit 33, a memory unit 34, a control unit 35, and an auxiliary reset command transmission unit 36.

  The transmission / reception unit 31 transmits / receives various commands and identification information 25b to / from the RFID tag 2 via the antenna 3a.

The division number designation unit 32 designates the number of time slots. According to a standard (for example, EPC Class-1 Generation 2 standard), the number of time slots is represented by 2 ^Q (Q is a positive integer), and Q is called a Q value. In the EPC Class-1 Generation 2 standard, Q is defined as 0 or more and 15 or less.

  When two or more RFID tags 2 respond and collision occurs in each time slot, the collision number acquisition unit 33 counts the collision number (collision number) as “1”. Based on the cumulative number of collisions, the division allocation unit 22 updates the number of time slots set in the next round.

  The memory unit 34 stores identification information 34 a acquired from each RFID tag 2 via the antenna 3 a and the transmission / reception unit 31.

  The control unit 35 includes a central processing unit (CPU), a read only memory (ROM) that stores various programs and control programs, and a random access memory (RAM) that temporarily stores data and the like, and controls circuits of the respective units.

  The auxiliary reset command transmission unit 36 transmits an auxiliary reset command to initialize the identification information 25b to the RFID tag 2 based on the information held in the auxiliary flag 24 via the transmission / reception unit 31 and the antenna 3a. Details of this auxiliary reset command will be described later.

  Next, the operation of the RFID system 1 will be described with reference to FIGS.

  2 is a schematic diagram showing an operation of a comparative example of the RFID system 1 in the embodiment of the present invention, FIG. 3 is a schematic diagram showing another operation of the comparative example of the RFID system 1, and FIG. 5 is a conceptual diagram for explaining the operation of the auxiliary flag 24 of the RFID tag, FIG. 5 is a schematic diagram of an operation before the RFID system 1 is initialized, and FIG. 6 is a schematic diagram of an operation after the RFID system 1 is initialized.

  First, in order to help understanding of the present embodiment, an operation of a comparative example with the present embodiment will be described with reference to FIGS. The reader / writer 3 reads the identification information 25b of the RFID tags 2a to 2f to be read in the communication area.

  As shown in FIG. 2, when a SELECT command as an initialization command is transmitted from the reader / writer 3 via the antenna 3a, among the RFID tags 2a to 2i moving in the P direction, the RFID tags in the communication area 100 2a to 2f are initialized. In FIG. 2, this initialization command sets the reading completion flag 25 a of the RFID tags 2 a to 2 f to “A” that has not been read. At this time, the RFID tags 2g to 2i outside the communication area 100 are not initialized.

  Next, a Query command is transmitted, and the Q value of the number of time slots is designated. For example, the Q value is “3”. Thus, the reader / writer 3 configures one round with eight time slots, and repeats the collection processing of the identification information 25b of the RFID tags 2a to 2f until there is no tag response in the round.

  In the RFID tags 2a to 2f, when a Query command is received via the tag antenna unit 20a and the transmission / reception unit 21, there are eight time slots according to the Q value (number of time slots) included in the Query command by the random number generation unit 23. One of these is assigned to the own device. Specifically, one value from “0” to “7” generated by the random number generation unit 23 is assigned and temporarily stored in the memory unit 25 as the slot counter information 25d. Here, for example, it is assumed that the slot counter information 25d of each of the RFID tags 2a to 2f is “2” “1” “3” “0” “5” “2”. With this slot counter information 25d, it is possible to control at what number of eight time slots the tag response is performed.

  Only the RFID tags 2a to 2f whose slot counter information 25d is “0” generate and transmit predetermined information for authentication, in this case, a hexadecimal random number (RN16). In the above example, since the slot counter information 25d of the RFID tag 2d is “0”, the RFID tag 2d generates and transmits a hexadecimal random number (RN16). This random number is temporarily stored in the memory unit 25 as random number information 25c. For example, it is assumed that this random number is “0xA12B”.

  The reader / writer 3 receives a random number from the RFID tag 2d via the antenna 3a and the transmission / reception unit 31, and determines that no collision has occurred when the random number can be read normally. Then, an Ack command having the received random number value “0xA12B” as an argument is transmitted to the RFID tag 2d.

  Each of the RFID tags 2a to 2f receives the Ack command and determines whether or not the same random number as the value “0xA12B” is stored in the memory unit 25. Here, since only the RFID tag 2d stores the value “0xA12B” as the random number information 25c in the memory unit 25, the RFID tag 2d transmits the identification information 25b stored in the memory unit 25 via the transmission / reception unit 21. Transmit to the reader / writer 3. Thereby, one tag is selected from the RFID tags 2a to 2f.

  The reader / writer 3 receives the identification information 25b of the selected RFID tag 2d by the transmission / reception unit 31, and stores the received identification information 25b in the memory unit 34 as the identification information 34a.

  In this way, the reader / writer 3 reads the identification information 25b of the RFID tag 2d assigned to the first time slot. On the other hand, in the RFID tag 2 d, when the identification information 25 b is normally read by the reader / writer 3, the control unit 26 sets the reading completion flag 25 a of the memory unit 25 to “B” that is reading completion. As a result, the RFID tag 2d is controlled by the control unit 26 so as not to respond to subsequent reading commands transmitted from the reader / writer 3.

  Next, the reader / writer 3 transmits a QueryRep command and advances the time slot number by one to “2”.

  The RFID tags 2a to 2c and the RFID tags 2e and 2f that have received the QueryRep command, except for the RFID tag 2d controlled to be non-responsive, decrement the value of the slot counter information 25d in the memory unit 25 by one. Thereby, in the RFID tags 2a to 2c and the RFID tags 2e and 2f, the respective slot counter information 25d becomes “1” “0” “2” “4” “1”.

  As a result, the RFID tag 2b responds in the second time slot. After acquiring the identification information 25b of the RFID tag 2b, the reader / writer 3 issues a QueryRep command and advances the time slot number by one to “3”. The RFID tag 2b sets the reading completion flag 25a to “B” indicating that reading is completed, and is controlled so as not to respond to a reading command transmitted from the reader / writer 3 in the same manner as the RFID tag 2d.

  Next, the RFID tags 2a, 2c, 2e, and 2f receive the QueryRep command and decrement the value of the slot counter information 25d in the memory unit 25 by one. Thereby, in the RFID tags 2a, 2c, 2e, and 2f, the slot counter information 25d becomes “0”, “1”, “3”, and “0”. In the third time slot, since the slot counter information 25d of the RFID tags 2a and 2f is “0”, the RFID tags 2a and 2f respond as shown in FIG. To the reader / writer 3.

  At this time, the reader / writer 3 receives a random number (RN16) as predetermined information from each of the RFID tags 2a and 2f, but cannot normally read due to a collision. From this, the collision number acquisition unit 33 determines that a collision has occurred, transmits a NAK command, and increments an internal counter (not shown) that counts the number of collisions by one. Accordingly, each of the RFID tags 2a and 2f does not transmit the identification information 25b to the reader / writer 3 via the transmission / reception unit 21, and accepts subsequent reading commands. That is, each of the RFID tags 2a and 2f leaves the reading completion flag 25a unread and does not set it.

  The RFID tags 2a and 2f set the slot counter information 25d to a predetermined maximum value, for example, “32767” that is “7FFF” in hexadecimal, by the QueryRep command. As a result, the slot counter information 25d is set to “0” by the QueryRep command within the same round, thereby preventing a response again.

  Then, the reader / writer 3 advances the time slot number by one to “4”. In the time slot “4”, the slot counter information 25d of the RFID tags 2a, 2c, 2e, and 2f becomes “32767”, “0”, “2”, and “32767” by sending the QueryRep command. Thereby, the RFID tag 2c responds similarly to the above. Thereafter, in the same manner, the RFID tag 2e responds in the time slot “6”. When the time slot number advances to “8”, the first round ends.

  However, since the reading of the RFID tags 2a and 2f still remains, the second round is executed. Similar to the first round, the RFID tags 2a and 2f are reassigned to any of the eight time slots. Then, for example, the reader / writer 3 acquires the identification information 25b of the RFID tags 2a and 2f with the time slots “2” and “4”.

  Next, the reader / writer 3 executes the third round to confirm whether or not the RFID tag 2 to be read due to a collision or the like really remains in the communication area 100, and tag responses are received in all eight time slots. If not, the reading process of the RFID tag 2 is terminated.

  Now that the outline of the operation of the RFID system 1 has been understood, the features of the present embodiment will be described.

  As shown in FIG. 2 and FIG. 3, since the RFID tag 2 is moving in the P direction, while the reading processing of the RFID tags 2a to 2f is being executed, as shown in FIG. Suppose that new RFID tags 2g to 2i are added to. In this case, since the reading completion flag 25a of the RFID tags 2g to 2i is undetermined in the initial state, initialization is necessary.

  When the newly added RFID tags 2g to 2i are initialized, all the RFID tags 2 in the communication area 100 are initialized together. Therefore, the reading completion flag 25a of the RFID tag 2d that has already been read is also set. It is initialized. As a result, the RFID tag 2d that has already been read is also read again, resulting in a problem that reading efficiency is lowered.

  Therefore, in the present embodiment, even if a new RFID tag is added in the communication area 100, the RFID system 1 has the RFID tags 2a to 2i that store and hold the identification information 25b. The reader / writer 3 reads the identification information 25b from each of the RFID tags 2a to 2i, and the RFID tags 2a to 2i read a reading completion flag 25a that holds information indicating whether or not the reading of the identification information 25b is completed, and a reading The reader / writer 3 has an auxiliary flag 24 that holds information indicating whether or not the completion flag 25a has been initialized, and a control unit 26 that operates the reading completion flag 25a or the auxiliary flag 24. The reader / writer 3 assists the reading completion flag 25a. An auxiliary reset instruction to be initialized based on the information of the flag 24 is applied to the RFID tags 2a to 2i. It is configured to have an auxiliary reset command transmitting unit 36 which transmits Te.

  The control unit 26 is configured to operate the auxiliary flag 24 to information indicating initialization when the reading completion flag 25a is initialized to be incomplete reading. Further, the control unit 26 is configured to initialize the reading completion flag 25a by an auxiliary reset command when the auxiliary flag 24 is information indicating non-initialization.

  Thereby, it becomes possible to initialize only the reading completion flag 25a of the RFID tags 2g to 2i by using the auxiliary reset command. For this reason, even if new RFID tags 2g to 2i (FIG. 3) are added to the communication area 100, the RFID tags 2a, 2d, Only the reading completion flag 25a of the new RFID tags 2g to 2i can be initialized without initializing the reading completion flag 25a of 2f, and the RFID tag 2d that has already been read is not duplicated. Thereby, a decrease in reading efficiency can be suppressed.

  When a normal initialization instruction (such as a SELECT command) is received, the read completion flag 25a is forcibly operated to a read incomplete state, and the auxiliary flag 24 is forcibly set to information indicating non-initialization. Operated.

  The auxiliary flag 24 is configured to switch to information indicating non-initialization when a predetermined time has elapsed after being operated on information indicating initialization.

For example, the auxiliary flag 24, as shown in FIG. 4, information indicating the initialization at time T ₁ (e.g., information of "1") when it is operated, a voltage based on a time constant from the time T ₁ of the predetermined 101 is gradually attenuated, voltage Va becomes upon reaching the time T _2, the process of comparison between a threshold value Va, switched on the information indicating the non-initialized.

As described above, the auxiliary flag 24 operates so as to hold information (for example, information of “1”) for a predetermined time (T ₂ −T ₁ ). The predetermined time may be set to a time sufficient for reading the RFID tag 2 and is set to about 1 (second), for example. The predetermined time constant decreases the voltage 101 in accordance with, for example, the time constant CR formed by the capacitor C and the resistor R.

  As described above, the auxiliary flag 24 is configured to hold information indicating initialization only for a predetermined time and switch to information indicating non-initialization when the predetermined time elapses. Therefore, the reader / writer installed in another location is used. 3, the read completion flag 25 a can be initialized again and the identification information 25 b can be read.

  The control unit 26 is configured to operate the auxiliary flag 24 to information indicating initialization when the information of the reading completion flag 25a is operated from reading incomplete to reading completion. Thereby, even if the auxiliary flag 24 switches to information indicating non-initialization after a predetermined time has elapsed, immediately after the reading is completed, the information indicating initialization can be operated again, and the reading is completed. The RFID tag 2 is not read redundantly. Thereby, a decrease in reading efficiency can be suppressed.

  Hereinafter, the operation of the RFID system 1 will be described with reference to FIGS. 5 and 6.

  As shown in FIG. 5, when an auxiliary reset command is transmitted from the antenna 3a of the reader / writer 3 in a state before initialization, the RFID tags 2a, 2d and 2f and the RFID tags 2g to 2i existing in the communication area 100 are transmitted. Among them, the reading completion flag 25a is manipulated by the control unit 26 of the RFID tags 2g to 2i so that the reading is not completed, and the auxiliary flag 24 is manipulated by information indicating initialization.

  As a result, as shown in FIG. 6, the state after the initialization is established, and the reading completion flag 25a of the RFID tags 2g to 2i is initialized to “A” which is not yet read. For example, the auxiliary flag 24 is set to “1” as unread information. The auxiliary flag 24 is automatically reset to “0” when a predetermined time has elapsed.

  Thereafter, the reader / writer 3 transmits a Query command to the RFID tags 2e, 2d, and 2f and the RFID tags 2g to 2i via the antenna 3a, and acquires time slot assignment and identification information 25b. Then, the reader / writer 3 subsequently transmits read commands such as a QueryRep command in order to acquire the identification information 25b of the RFID tags 2e and 2f and the RFID tags 2g to 2i.

  As described above, according to the present embodiment, the RFID system 1 includes the RFID tags 2a to 2i that store and hold the identification information 25b, and the reader / writer 3 that reads the identification information 25b from each of the RFID tags 2a to 2i. The RFID tags 2a to 2i each have a reading completion flag 25a that holds information indicating whether or not the reading of the identification information 25b has been completed, and an auxiliary flag 24 that holds information whether or not the reading completion flag 25a has been initialized. The reader / writer 3 has an auxiliary reset command that initializes the reading completion flag 25a based on the information of the auxiliary flag 24 to the RFID tags 2a to 2i. The auxiliary reset command transmission unit 36 is configured to transmit to the remote reset command transmission unit 36.

  Thereby, it becomes possible to initialize only the reading completion flag 25a of the RFID tags 2g to 2i by using the auxiliary reset command. For this reason, even if new RFID tags 2g to 2i (FIG. 3) are added to the communication area 100, the RFID tags 2a, 2d, Only the reading completion flag 25a of the new RFID tags 2g to 2i can be initialized without initializing the reading completion flag 25a of 2f, and the RFID tag 2d that has already been read is not duplicated. Thereby, a decrease in reading efficiency can be suppressed.

As described above, according to the present invention, the RFID tag has a reading completion flag that holds information indicating whether or not reading of identification information has been completed, and an auxiliary that holds information that indicates whether or not the reading completion flag has been initialized. An auxiliary reset having a flag and a control unit for operating a reading completion flag or an auxiliary flag, and the reader / writer transmits an auxiliary reset command for initializing the reading completion flag to the RFID tag based on the information of the auxiliary flag When the auxiliary flag is information indicating non-initialization, the RFID tag control unit initializes the read completion flag to read incomplete and initializes the auxiliary flag by the auxiliary reset command transmitted by the reader / writer. The information indicating initialization is operated to enter the initialized state, and the identification information is read by the reader / writer in the initialized state. The read complete flag is set to read complete, and the read reset flag sent from the reader / writer is not initialized without using the auxiliary reset command sent by the reader / writer to initialize the read complete flag to read incomplete. Since the auxiliary flag is configured to switch to information indicating non-initialization when a predetermined time has elapsed after operating on information indicating initialization, the reader / writer installed elsewhere The RFID tag that has already been read in is not read redundantly, and only the read completion flag of a new RFID tag that has not been initialized can be initialized again by using the auxiliary reset command. It becomes.

  For this reason, even if a new RFID tag is added to the communication area, only a new RFID tag read completion flag is initialized without initializing a read completion flag of an already initialized RFID tag among a plurality of RFID tags. The RFID tag that has already been read is not duplicated. This is useful as an RFID system capable of suppressing a decrease in reading efficiency.

Schematic diagram of an RFID system according to an embodiment of the present invention Schematic diagram showing the operation of a comparative example of the RFID system Schematic diagram showing another operation of the comparative example of the RFID system Conceptual diagram for explaining the operation of the auxiliary flag of the RFID tag in the RFID system Overview of operation before initialization of the RFID system Overview of operation after initialization of the RFID system

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 RFID system 2a-2i RFID tag 3 Reader / writer 3a Antenna 4 Management article 20a Tag antenna part 20b Tag circuit part 21, 31 Transmission / reception part 22 Division allocation part 23 Random number generation part 24 Auxiliary flag 25, 34 Memory part 25a Reading completion flag 25b , 34a Identification information 25c Random number information 25d Slot counter information 26, 35 Control unit 32 Division number designation unit 33 Collision number acquisition unit 36 Auxiliary reset command transmission unit 100 Communication area

Claims (3)

Comprising a plurality of RFID tags holds storing identification information, and a reader-writer for reading the identification information from each of the plurality of RFID tags,
Each of the plurality of RFID tags includes a read completion flag that holds information indicating whether or not reading of the identification information has been completed, an auxiliary flag that holds information whether or not the read completion flag has been initialized, a control unit for operating the read completion flag or the auxiliary flag and,
The reader / writer has an auxiliary reset command transmission unit that transmits an auxiliary reset command for initializing the reading completion flag based on information of the auxiliary flag to the plurality of RFID tags ,
The control unit of each of the plurality of RFID tags is
When the auxiliary flag is information indicating non-initialization, the reading completion flag is initialized to read incomplete and the auxiliary flag is initialized to information indicating initialization by an auxiliary reset command transmitted by the reader / writer. In a later state,
When the identification information is read by the reader / writer in the state after the initialization, the reading completion flag is set to reading completion, and the reading completion flag is not read by using the auxiliary reset command transmitted by the reader / writer. Without initialization to completion, control to non-response to subsequent read commands sent from the reader / writer,
The RFID system according to claim 1, wherein the auxiliary flag is switched to information indicating non-initialization when a predetermined time elapses after being operated on information indicating initialization . 2. The RFID system according to claim 1 , wherein the control unit is configured to operate the auxiliary flag to information indicating initialization when the information of the reading completion flag is operated from reading incomplete to reading completion. . When the control unit of the RFID tag receives a normal initialization command, the reading completion flag is forcibly operated to a state of incomplete reading, and the auxiliary flag is forcibly operated to information indicating non-initialization. The RFID system according to claim 1 or 2, characterized in that:

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