JP7278140B2 - Wireless tag reader and program - Google Patents

Description

The embodiments of the present invention relate to a wireless tag reader and program.

2. Description of the Related Art Conventionally, by reading data stored in a wireless tag, the inventory and incoming/outgoing of articles to which the wireless tag is attached have been managed. A wireless tag is, for example, a tag (IC tag) including an IC chip capable of remotely reading data using radio waves of a predetermined frequency band. For reading data, for example, RFID (Radio Frequency IDentification), that is, automatic recognition technology using short-range wireless communication is used.

For example, data registered in a large number of wireless tags may be read when inventory management is performed using RFID. In such a case, the wireless tag generates RN16, which is a 16-bit random number, and transmits it to the reader. Then, the wireless tag confirms that the transmitted RN16 is included in the reply including the RN16 from the reader, and transmits its own information. A technique has been proposed for reading information possessed by a plurality of wireless tags by following such procedures (for example, Patent Literature 1).

However, with such a conventional wireless tag reader, there is a possibility that multiple tags will return the same RN16 with a probability of 1/2 ¹⁶ (=1/65536). This probability is very small, but if the number of tags increases, the probability of returning the same RN16 increases. For example, if there are n tags, the probability that multiple tags will return the same RN16 is 1-(65535/65536)^(n-1). That is, if there are 1000 tags, there is a probability of about 1.5% that multiple tags will return the same RN16. In addition, when multiple tags return the same RN16, there is a problem that wireless tags are not read.

The problem to be solved by the present invention is to provide a wireless tag reader and a program capable of reliably reading the information of the wireless tags without fail even when the number of wireless tags is large. .

A wireless tag reader according to an embodiment reads information on a wireless tag, and includes reading means, specifying means, and reading control means. The reading means reads information from the wireless tag. The designation means sets the reading state by the reading means to the first inhibition time period for the response from the wireless tag when the reading means reads the response of the wireless tag and continues the periodic power supply to the wireless tag. and a first reading state in which, after reading the response from the wireless tag by the reading means, the response from the wireless tag is suspended for the second suppression time regardless of whether or not power is supplied to the wireless tag. and a second reading state in which the response from the wireless tag is suppressed in the third suppression time when the periodic power supply to the wireless tag is continued after the reading means reads the response of the wireless tag. and a fourth reading state in which a response from the wireless tag is suppressed when power is continuously supplied to the wireless tag after the reading means reads the response from the wireless tag. Set to either the state or The reading control means, after starting reading in the reading state specified by the specifying means, does not complete reading of all the wireless tags, and a first predetermined time set according to the number of wireless tags elapses. the reading state of the reading means is changed from the first reading state or the third reading state to the second reading state or the fourth reading state or the third reading state or the first reading state Outputs a switching trigger signal.

FIG. 1 is an external view showing an example of an RFID tag reader according to an embodiment. FIG. 2 is a diagram showing an example of the internal structure of the RFID tag reader. FIG. 3 is a block diagram showing an example of the hardware configuration of the RFID tag reader. FIG. 4 is a block diagram showing an example of the hardware configuration of the RFID tag. FIG. 5 is a state transition diagram of the RFID tag when the RFID tag reader reads the RFID tag. FIG. 6 is a diagram showing an example of inventory flag maintenance time in each session of the RFID tag. FIG. 7 is a block diagram showing an example of the functional configuration of the RFID tag reader. FIG. 8 is a diagram showing an example of a user interface screen displayed when operating the RFID tag reader. FIG. 9 is a state transition diagram showing an example of read state transition of the RFID tag reader. FIG. 10 is a flow chart showing an example of the flow of reading processing performed by the RFID tag reader. FIG. 11 is a diagram showing an example of a user interface screen displayed when operating the RFID tag reader according to the second embodiment. FIG. 12 is a flow chart showing an example of the flow of reading processing performed by the RFID tag reader of the second embodiment.

(First embodiment)
An RFID tag reader according to an embodiment will be described below with reference to the drawings. An RFID tag reader is a device that reads information stored in an RFID tag without contact. In addition, this invention is not limited by embodiment described below.

(Description of RFID tag reader)
An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing an example of the appearance of an RFID tag reader according to an embodiment. The RFID tag reader 10 shown in FIG. 1 has a walk-through configuration, for example, reads information from an RFID tag 50 (see FIG. 2) attached to an article 42 that is packed in a packing material 40 and conveyed. is read in a non-contact manner, entry/exit management of the article 42 is performed. Articles 42 are received and delivered in order of, for example, 1000 pieces, and information is read by the RFID tag reader 10 each time.

Also, FIG. 2 is a diagram showing an example of the internal structure of the RFID tag reader. The form of the RFID tag reader 10 is not limited to the form shown in FIGS. 1 and 2, and may be a handy type RFID reader.

As shown in FIG. 1, the RFID tag reader 10 includes a shield 12, antennas 14a and 14b, a reader 16, and a display operation device . The RFID tag reader 10 is an example of a wireless tag reader.

The shielding portion 12 has a tunnel shape and has a pair of openings 12a and 12b. The worker 46 places the article 42 packed in the packing material 40 on the cart 44 and carries it in through the opening 12a. Then, the worker 46 advances inside the shielding portion 12 and carries out the article 42 from the opening portion 12b. That is, article 42 moves along the y-axis.

The antennas 14a and 14b radiate radio waves of predetermined frequencies to the article 42. FIG. Also, the antennas 14 a and 14 b receive response waves from the article 42 . At this time, the shielding portion 12 prevents the radio waves radiated from the antennas 14a and 14b from leaking to the outside, and blocks the entry of radio waves from the outside.

The reader 16 instructs the antennas 14a and 14b to transmit and receive radio waves, and the reader 16 retrieves information related to the article 42 stored in the RFID tag 50 from among the response waves received by the antennas 14a and 14b. (For example, an identification number that uniquely identifies the article 42, etc.) is extracted. Note that the reader 16 may be a reader/writer that reads data from the RFID tag 50 and also writes or rewrites data to the RFID tag 50 .

The display operation device 18 accepts settings such as inputting the total amount of the articles 42 in advance. Also, the display operation device 18 displays the reading result of the reader 16 . The display operation device 18 is, for example, a liquid crystal display with a touch panel. Also, the display operation device 18 may be a mobile terminal or a tablet terminal possessed by the worker 46 . The hardware configuration of the RFID tag reader 10 will be described later in detail (see FIG. 3).

The RFID tag 50 is a storage medium from which data can be remotely read (or rewritten) using radio waves of a predetermined frequency band. The RFID tag 50 includes an IC chip and an antenna, stores data in the IC chip, and operates when the antenna receives radio waves to transmit or rewrite data in the IC chip. The RFID tag 50 is attached (attached or attached) to an article such as a product. Note that the RFID tag 50 is an example of a wireless tag. The hardware configuration of the RFID tag 50 will be detailed later (see FIG. 4).

As shown in FIG. 2, the antennas 14a and 14b are installed on the left and right sides with respect to the direction in which the article 42 travels. The antennas 14a and 14b irradiate the article 42 with radio waves from different directions. As a result, the article 42 is evenly irradiated with radio waves, so that the information on the RFID tag 50 can be reliably read. The number and installation positions of the antennas 14a and 14b are not limited to those illustrated in FIG.

The antennas 14a and 14b radiate radio waves to radiation ranges 15a and 15b shown in FIG. 2, respectively. In order to prevent interference, the antennas 14a and 14b transmit radio waves in a time division manner according to instructions from the reader 16. FIG.

An article 42 with an RFID tag 50 passes through the radiation ranges 15a and 15b of the antennas 14a and 14b while being packed inside the packing material 40, as shown in FIG.

(Hardware configuration of RFID tag reader)
Next, the hardware configuration of the RFID tag reader 10 will be described with reference to FIG. FIG. 3 is a block diagram showing an example of the hardware configuration of the RFID tag reader. The RFID tag reader 10 includes a reader 16, a display device 18a, an operation device 18b, and antennas 14a and 14b. The reader 16 includes a control section 22 , a storage section 23 , a peripheral device controller 25 and a communication interface 26 .

The control unit 22 includes a CPU (Central Processing Unit) 22a, a ROM (Read Only Memory) 22b, and a RAM (Random Access Memory) 22c. The CPU 22a is connected via the bus line 24 to the ROM 22b and the RAM 22c. The CPU 22a expands the control program P1 stored in the ROM 22b or the storage unit 23 to the RAM 22c. The CPU 22a controls the operation of the reader 16 by operating according to the control program P1 developed in the RAM 22c. That is, the control unit 22 has a configuration of a general computer.

The control unit 22 is further connected to a storage unit 23 , a peripheral device controller 25 and a communication interface 26 via a bus line 24 .

The storage unit 23 is a non-volatile memory such as a flash memory, a HDD (Hard Disk Drive), or the like, which retains stored information even when the power is turned off. The storage unit 23 stores programs including the control program P1. The control program P1 is a program for exerting the functions of the reader 16 .

It should be noted that the control program P1 may be provided by being incorporated in the ROM 22b in advance. The control program P1 is a file in a format that can be installed in the control unit 22 or in an executable format, and can be read by a computer such as a CD-ROM, a flexible disk (FD), a CD-R, and a DVD (Digital Versatile Disc). It may be configured to be recorded on a suitable recording medium and provided. Furthermore, the control program P1 may be stored on a computer connected to a network such as the Internet and provided by being downloaded via the network. Also, the control program P1 may be configured to be provided or distributed via a network such as the Internet.

Further, the storage unit 23 stores an article master M. FIG. The article master M is a master file storing information (article code, product name, price, etc.) of the article 42 subject to warehousing/delivery management. The information in the article master M is used to calculate the total amount of articles 42 subject to storage/delivery management. Used for confirmation.

The peripheral device controller 25 connects with the display device 18a, the operation device 18b, and the antennas 14a and 14b. The display device 18a is, for example, a liquid crystal display. The operation device 18b is, for example, a touch panel superimposed on the display device 18a. The aforementioned display operation device 18 (FIG. 1) is composed of a display device 18a and an operation device 18b. Also, the functions of the antennas 14a and 14b are as described above. The peripheral device controller 25 controls operations of connected hardware based on commands from the control unit 22 . Note that the display operation device 18 may have a keyboard instead of the touch panel as the operation device 18b.

The communication interface 26 receives the article master M and transmits information read by the RFID tag reader 10, for example, by communicating with a server device (not shown) or the like.

(Hardware configuration of RFID tag)
Next, the hardware configuration of the RFID tag 50 will be explained using FIG. FIG. 4 is a block diagram showing an example of the hardware configuration of the RFID tag.

The RFID tag 50 includes an antenna 51 , a transmission/reception section 52 , a control section 53 , an electromotive force section 54 and a memory 55 . The antenna 51 receives radio waves radiated from the antennas 14 a and 14 b of the RFID tag reader 10 . The transmitter/receiver 52 transmits and receives radio waves through the antenna 51 . The control unit 53 controls the entire operation related to reading the RFID tag 50 . The electromotive force unit 54 generates electric power for activating the RFID tag 50 based on radio waves received by the antenna 51 from the RFID tag reader 10 . The electromotive force unit 54 also generates power for controlling transmission of information (tag information) registered in the RFID tag 50 to the RFID tag reader 10 . The memory 55 stores article information of the article 42 to which the RFID tag 50 is attached, tag information specifying the RFID tag 50, and the like.

(Description of RFID tag reading function)
Next, the RFID tag reading function of the RFID tag reader 10 will be briefly described with reference to FIG. It is assumed that the RFID tag reader 10 has an RFID tag reading function conforming to the air interface of ISO18000-63 (GS1). FIG. 5 is a state transition diagram of the RFID tag when the RFID tag reader reads the RFID tag. Note that FIG. 5 shows only the main part of the state transition of the RFID tag 50 .

When the RFID tag 50 in the power OFF state T1 moves into the antenna communication area, it transitions to the standby state T2.

When the RFID tag 50 is in the standby state T2 and receives a Query command from the reader 16, the RFID tag 50 transitions to the arbitration state T3. A Query command is a command by which the reader 16 queries the RFID tag 50 for participation in an inventory that identifies an individual tag among a plurality of tags. Note that, when in the arbitration state T3, the RFID tag 50 arbitrates so as not to respond to the reader 16 at the same time.

When the RFID tag 50 is in the arbitration state T3 and receives a Query Adjust command or a Query Rep command from the reader 16, the RFID tag 50 transitions to the response state T4. When in response state T4, the target RFID tag 50 generates RN16, which is a 16-bit random number, and transmits it to the reader 16. FIG.

When the RFID tag 50 is in the response state T4 and receives an Ack command, which is a response signal including RN16, transmitted from the reader 16, the RFID tag 50 includes the RN16 transmitted by itself in the Ack command. to detect whether Then, when it is detected that RN16 is included, RFID tag 50 transitions to approval state T5. When in the approval state T5, the RFID tag 50 transmits an EPC (Electronic Product Code), which is an identification code related to product information stored therein.

Note that the arbitration state T3, the response state T4, and the approval state T5 are so-called states in which, when reading information from a plurality of RFID tags 50, collision of information from each tag is avoided and information from each tag is read. Configure an inventory process T6 for realizing anti-collision.

When the RFID tag 50 is in the acknowledged state T5 and receives a Req_RN command from the reader 16, the RFID tag 50 transitions to the open state T7.

When the RFID tag 50 is in the open state T7 and receives a Select command from the reader 16, the RFID tag 50 transitions to the standby state T2. When the RFID tag 50 is in the open state T7 and receives a Kill command from the reader 16, the RFID tag 50 transitions to the function stop state T9.

Further, when the RFID tag 50 is in the open state T7 and receives an Access command from the reader 16, the RFID tag 50 transitions to the secure state T8.

When the RFID tag 50 is in the secure state T8 and receives a Select command from the reader 16, the RFID tag 50 transitions to the standby state T2. Further, when the RFID tag 50 is in the secure state T8 and receives a Kill command from the reader 16, the RFID tag 50 transitions to the function stop state T9.

When the RFID tag 50 moves out of the antenna communication area while the RFID tag 50 is in the function stop state T9, the RFID tag 50 transitions to the power OFF state T1.

By performing the above-described series of processes in cooperation with the reader 16, the RFID tag 50 can read a plurality of RFID tags 50 without fail.

(Description of persistence time)
The RFID tag reader 10 reads information from the RFID tag 50 by executing one of four independent sessions S0, S1, S2, and S3. Specifically, the RFID tag reader 10 selects one of the four types of sessions S0, S1, S2, and S3, and uses the selected session as the Query command, Query Adjust command, and Query Rep command. specified by Furthermore, the RFID tag reader 10 designates the state of the inventory flag of the RFID tag 50 to be read using the Query command. The fact that the inventory flag is on (the inventory flag is in the A state) means that the RFID tag 50 has not responded. Also, the fact that the inventory flag is off (the inventory flag is in the B state) means that the RFID tag 50 has responded. The RFID tag reader 10 designates, for example, reading only tags with inventory flag A in session S2 by means of a Query command. Hereafter, reading a tag with only inventory flag A in session Sn is described as Sn_A (n=0, 1, 2, 3).

The inventory flag provided in the RFID tag 50 has a persistence time corresponding to each session. The persistence time is the time from when the power supply to the RFID tag 50 is stopped until the inventory flag that has become a response is changed to the non-response state again.

Here, the persistence time of the RFID tag 50 will be described with reference to FIG. FIG. 6 is a diagram showing an example of inventory flag maintenance time in each session of the RFID tag.

In session S0, if the RFID tag 50 continues to be powered continuously, the inventory flag will continue to be maintained. On the other hand, if the RFID tag 50 is not powered, the inventory flag immediately (0s) reverses state (A→B or B→A). 0s in this case is the persistence time. Note that session S0 is an example of a fourth reading state.

In session S1, the inventory flag continues to be maintained for 500ms to 5s regardless of whether power is supplied to the RFID tag 50 or not. After 500 ms to 5 s, the inventory flag reverses its state. 500 ms to 5 s in this case is the persistence time. Note that the period of 500 ms to 5 s is an example of the second suppression time. Also, session S1 is an example of a second reading state.

In session S2, if the RFID tag 50 continues to be powered periodically, the inventory flag will continue to be maintained. On the other hand, if the RFID tag 50 is not powered, the inventory flag continues to be maintained for 2 seconds or more. Then, after a period of 2s or more has passed, the inventory flag reverses its state. The time of 2 seconds or longer in this case is the persistence time. Note that the time of 2 seconds or more is an example of the first suppression time. Also, session S2 is an example of a first reading state.

Session S3 continues to maintain the inventory flag if it continues to power the RFID tag 50 regularly. On the other hand, if the RFID tag 50 is not powered, the inventory flag continues to be maintained for 2 seconds or more. Then, after a period of 2s or more has passed, the inventory flag reverses its state. The time of 2 seconds or longer in this case is the persistence time. Note that the time of 2 seconds or more is an example of the third suppression time. Note that session S3 is an example of a third reading state.

By having such a persistence time, the RFID tag reader 10 reads the RFID tag 50 that could not be read in the first reading, when the persistence time has passed and the inventory flag is changed to a non-response state. can be read again.

(Functional configuration of RFID tag reader)
Next, the functional configuration of the RFID tag reader 10 will be described with reference to FIG. FIG. 7 is a block diagram showing an example of the functional configuration of the RFID tag reader. The control unit 22 of the RFID tag reader 10 (reader 16) develops the control program P1 in the RAM 22c and operates it to obtain the tag quantity acquisition unit 61, the reading state designation unit 62, and the signal reading unit shown in FIG. 63, a clock unit 64, a reading operation control unit 65, an operation control unit 66, and a display control unit 67 are implemented as functional units.

The tag quantity acquisition unit 61 acquires the quantity N of the RFID tags 50 read by the RFID tag reader 10 . Specifically, the number N of the RFID tags 50 is acquired based on the file name of the article master M or the total amount of the articles 42 input to the start screen G1 (see FIG. 8A), which will be described later.

The reading state designating section 62 (designating means) designates the reading state by the signal reading section 63 (reading means) as a first reading state, a second reading state, a third reading state, and a fourth reading state. , or any reading state.

In the first reading state, after the signal reading unit 63 reads the response of the RFID tag 50, when the periodic power supply to the wireless tag is continued, the response from the RFID tag 50 is first suppressed. It is a read state that inhibits over time (eg, session S2 above).

In the second reading state, after the signal reading unit 63 reads the response from the RFID tag 50, the response from the RFID tag 50 is kept for the second suppression time regardless of whether power is supplied to the wireless tag. It is a reading state that is suppressed by pressing (for example, the above-described session S1).

In the third reading state, after the signal reading unit 63 has read the response of the RFID tag 50, when the periodic power supply to the wireless tag is continued, the response from the RFID tag 50 is suppressed in the third mode. It is a reading state that inhibits over time (eg, session S3 above).

The fourth reading state is a reading state in which the response from the RFID tag 50 is suppressed when power is continuously supplied to the RFID tag 50 after the signal reading unit 63 has read the response of the RFID tag 50 . (eg, session S0 described above).

The signal reading unit 63 (reading means) receives the reflected wave of the radio wave emitted to the RFID tag 50 (wireless tag) and reads the information of the RFID tag 50 . Also, the signal reading unit 63 determines whether all the RFID tags 50 have been read. Whether or not all RFID tags 50 have been read is determined by whether the number of read RFID tags 50 matches the number N of RFID tags 50 .

The timer 64 sets a first predetermined time t1, which is a threshold of the time from the start of reading in the reading state specified by the reading state specifying unit 62 to the completion of reading of all the RFID tags 50. . Specifically, the first predetermined time t1 is set on a later-described setting screen G2 (see FIG. 8B). In addition, the timer 64 measures the elapsed time ta from when the signal reader 63 starts the reading operation.

The reading operation control section 65 (reading control means) outputs a trigger signal to the reading state specifying section 62 to change the reading state of the signal reading section 63 from the first reading state or the third reading state to the third reading state. 2 reading state or the fourth reading state, or the third reading state or the first reading state.

Note that the reading operation control unit 65 outputs a trigger signal on condition that a predetermined operation instruction is received. When the reading operation control unit 65 starts reading in the reading state specified by the reading state specifying unit 62 and the reading of all the RFID tags 50 is not completed and the first predetermined time t1 elapses, Outputs a trigger signal. For example, 120 s is set as the first predetermined time t1. Although it depends on the number of RFID tags 50 to be read, sessions S2 and S3 generally complete reading faster than sessions S0 and S1. , may be set shorter than the first predetermined time t1 for the sessions S0 and S1.

The operation control unit 66 receives an operation on the display operation device 18 (for example, touch panel).

The display control unit 67 displays tag information read by the RFID tag reader 10, information related to the operating state of the RFID tag reader 10, and the like on the display operation device 18 (display device 18a). The display control unit 67 also displays buttons and the like for giving operation instructions to the RFID tag reader 10 .

(Explanation of user interface)
Next, a user interface for operating the RFID tag reader 10 will be described with reference to FIG. FIG. 8 is a diagram showing an example of a user interface screen displayed when operating the RFID tag reader.

Before the RFID tag reader 10 starts operating, the display control unit 67 displays a start screen G1 shown in FIG. 8A on the display operation device 18 (display device 18a). A file name designation field 81, an RFID tag total amount designation field 82, a setting button 83, and a start button 84 are displayed on the start screen G1.

The file name designation field 81 is a field for designating the file name of the article master M storing the information of the article 42 to be read by the RFID tag reader 10 from now on. Further, the RFID tag total amount designation field 82 is a field for designating the total amount of the articles 42 to be read by the RFID tag reader 10 .

If the operator of the RFID tag reader 10 knows the file name of the article master M that stores the information of the article 42 to be read, he/she enters the file name in the file name specification field 81 . On the other hand, if the file name of the item master M is not known, the total amount of the items 42 is entered in the RFID tag total amount specification field 82 .

Note that when the file name designation field 81 is pressed, the display control unit 67 pops up an alphabet and numeric input screen on the display operation device 18 . Further, when the RFID tag total amount specification field 82 is pressed, the display control unit 67 pops up the 10-key screen on the display operation device 18 . The operator inputs a predetermined file name or the total amount of the articles 42 (RFID tags 50) by operating the pop-up alphabetical and numeric input screen or the ten-key screen.

The setting button 83 is a button for calling a setting screen G2 for performing necessary settings when the RFID tag reader 10 reads the RFID tag 50 . Note that the setting screen G2 will be described later.

The start button 84 is a button for instructing the RFID tag reader 10 to start reading the RFID tag 50 .

The setting screen G2, as shown in FIG. 8B, is a screen for setting an automatic recovery function, a session transition state (recovery mode), and a first predetermined time t1. The operator of the RFID tag reader 10 selects each item and inputs a numerical value by specifying a predetermined position.

The automatic recovery function is a function for automatically switching sessions when a first predetermined time t1 has passed since the session was started. The function is enabled by setting the item of the automatic recovery function to ON. On the other hand, when the automatic recovery function is set to OFF, session switching is performed according to an operator's instruction (pressing a recovery button 86, which will be described later).

The session transition state (recovery mode) is an item that specifies the session to be used and its switching order. FIG. 8(b) shows an example in which the session transition state is specified to perform session S1 after session S2, that is, to switch from the first reading state to the second reading state.

The item of end/recovery time setting is an item for setting a first predetermined time t1. The first predetermined time t1 is determined by the timer unit 64 based on the total amount of the articles 42 read from the article master M set on the start screen G1 or the total amount of the articles 42 entered in the RFID tag total amount designation field 82. It may be calculated automatically. In general, the greater the total amount of articles 42 (the greater the total amount of RFID tags 50), the longer the time required to read all RFID tags 50, so it is desirable to set the first predetermined time t1 longer.

When the RFID tag reader 10 starts reading, the display control unit 67 displays the operation control screen G3 shown in FIG. 8C on the display operation device 18. FIG. The operation control screen G3 includes a read stop button 85 and a recovery button 86 .

The read stop button 85 is a button that causes the RFID tag reader 10 to end the reading operation according to an operator's instruction. The reading stop button 85 is used, for example, to stop reading after it has started.

The recovery button 86 is a button for instructing session switching according to an operator's instruction. That is, when the recovery button 86 is pressed, the reading state designating section 62 (designating means) generates a trigger signal to switch the session currently being read to the session designated on the setting screen G2.

Although not shown in FIG. 8C, the display control unit 67 displays the contents of the read RFID tag 50 (article code, article name, quantity, etc.) on the operation control screen G3 at any time.

(Transition of reading state of RFID tag reader)
Next, the transition of the reading state in the RFID tag reader 10 will be described with reference to FIG. FIG. 9 is a state transition diagram showing an example of read state transition of the RFID tag reader.

The RFID tag reader 10 first performs reading only in session S2_A or only in session S3_A (reading state T11).

In reading state T11, if the first predetermined time t1 has passed without reading all the RFID tags 50 (condition V), reading is performed only in session S1_A or only in session S0_A (reading state T12). .

Further, when the recovery button 86 is pressed in the reading state T11 (condition W), reading is performed only in session S1_A or only in session S0_A (reading state T12).

Note that the RFID tag reader 10 may perform other session switching. That is, in the reading state T11, when the first predetermined time t1 has elapsed without reading all the RFID tags 50 (condition V), reading may be performed only in session S3_A or only in session S2_A. (Reading state T13).

Further, when the recovery button 86 is pressed in the reading state T11 (condition W), reading may be performed only in session S3_A or only in session S2_A (reading state T13).

Furthermore, in the reading state T13, when the first predetermined time t1 has passed without reading all the RFID tags 50 (condition V), the RFID tag reader 10 reads only the session S1_A or only the session S0_A. (reading state T12).

Further, when the recovery button 86 is pressed in the reading state T13 (condition W), reading may be performed only in session S1_A or only in session S0_A (reading state T12).

Which session is switched depends on the setting on the setting screen G2.

(Flow of processing performed by RFID tag reader)
Next, the flow of processing performed by the RFID tag reader 10 will be described with reference to FIG. FIG. 10 is a flow chart showing an example of the flow of reading processing performed by the RFID tag reader. Note that FIG. 10 shows, as an example, the flow of processing when the reading state T11 transitions to the reading state T12.

The tag quantity acquisition unit 61 acquires the quantity N of the RFID tags 50 (step S11).

The timer 64 sets the first predetermined time t1 (step S12). It should be noted that the first predetermined time t1 may be set by a value input to the setting screen G2, or may be calculated by the timer 64 based on the number N of RFID tags 50. FIG.

The timer 64 resets the elapsed time ta (step S13). Note that the elapsed time ta is a time representing an elapsed time from the start of the session, and is a time used for evaluating whether the elapsed time ta exceeds the first predetermined time t1.

The reading state designating unit 62 designates the reading state as session S2_A (or S3_A), that is, the first reading state (or third reading state), and the signal reading unit 63 detects the radio wave irradiated to the RFID tag 50. A reflected wave is read (step S14).

The signal reading unit 63 determines whether all RFID tags 50 have been read (step S15). When it is determined that all the RFID tags 50 have been read (step S15: Yes), the RFID tag reader 10 ends the processing of FIG. On the other hand, if it is not determined that all the RFID tags 50 have been read (step S15: No), the process proceeds to step S16.

If determined as No in step S15, the reading operation control unit 65 determines whether the reading stop button 85 (FIG. 8(c)) has been pressed (step S16). If it is determined that the reading stop button 85 has been pressed (step S16: Yes), the process proceeds to step S17. On the other hand, if it is not determined that the reading stop button 85 has been pressed (step S16: No), the process proceeds to step S18.

When determined as No in step S16, the timer 64 determines whether the elapsed time ta is equal to or longer than the first predetermined time t1 (step S18). If it is determined that the elapsed time ta is equal to or longer than the first predetermined time t1 (step S18: Yes), the process proceeds to step S19. On the other hand, if it is determined that the elapsed time ta is not longer than the first predetermined time t1 (step S18: No), the process returns to step S14 to continue reading the RFID tag 50. FIG.

On the other hand, if determined as Yes in step S16, the reading operation control unit 65 determines whether the reading stop button 85 or the recovery button 86 was pressed (step S17). When it is determined that the reading stop button 85 has been pressed, the RFID tag reader 10 ends the processing of FIG. On the other hand, if it is determined that the recovery button 86 has been pressed, the process proceeds to step S19.

If it is determined as Yes in step S18 or if it is determined that the recovery button 86 has been pressed in step S17, the timer 64 resets the elapsed time ta (step S19). At this time, the reading operation control section 65 outputs a trigger signal to the reading state designating section 62 .

Next, the reading state designation unit 62 receives a trigger signal from the reading operation control unit 65 and designates the reading state as session S1_A (or S0_A), that is, the second reading state (or fourth reading state). Then, the signal reading unit 63 reads the reflected wave of the radio wave irradiated to the RFID tag 50 (step S20).

The signal reading unit 63 determines whether all RFID tags 50 have been read (step S21). When it is determined that all the RFID tags 50 have been read (step S21: Yes), the RFID tag reader 10 ends the processing of FIG. On the other hand, if it is not determined that all the RFID tags 50 have been read (step S21: No), the process proceeds to step S22.

When determined as No in step S21, the reading operation control unit 65 determines whether the reading stop button 85 has been pressed (step S22). If it is determined that the reading stop button 85 has been pressed (step S22: Yes), the RFID tag reader 10 ends the processing of FIG. On the other hand, if it is not determined that the reading stop button 85 has been pressed (step S22: No), the process proceeds to step S23.

When determined as No in step S22, the timer 64 determines whether the elapsed time ta is equal to or greater than the first predetermined time t1 (step S23). When it is determined that the elapsed time ta is equal to or longer than the first predetermined time t1 (step S23: Yes), the RFID tag reader 10 terminates the processing of FIG. On the other hand, if it is not determined that the elapsed time ta is equal to or longer than the first predetermined time t1 (step S23: No), the process returns to step S20 to continue reading the RFID tag 50. FIG.

Also, when the RFID tag reader 10 changes the reading state from the reading state T11 to the reading state T13, and when the reading state changes from the reading state T11 to the reading state T12 via the reading state T13, The flow is similar to that of FIG.

As described above, in the RFID tag reader 10 of the first embodiment, the reading state designating section 62 (designating means) sets the reading state of the signal reading section 63 (reading means) to the RFID tag 50 (wireless tag). After the signal reading unit 63 reads the response from the RFID tag 50, when the regular power supply to the RFID tag 50 is continued, the response from the RFID tag 50 is suppressed for the first suppression time. After the signal reading unit 63 reads the state and the response of the RFID tag 50, the response from the RFID tag 50 is suppressed for the second suppression time regardless of whether power is supplied to the RFID tag 50. 2, and when the signal reading unit 63 reads the response of the RFID tag 50, the periodic power supply to the RFID tag 50 is continued, the response from the RFID tag 50 is set to the third suppression time. and a third read state in which the response from the RFID tag 50 is inhibited over a and the fourth read state to be suppressed. Then, the reading operation control section 65 (reading control means) changes the reading state of the signal reading section 63 from the first reading state or the third reading state to the second reading state or the fourth reading state, or A trigger signal for switching to the third reading state or the first reading state is output. Therefore, for example, by switching from a read state with a long persistence time to a read state with a short persistence time, it is possible to read the RFID tag 50 that has been missed. Also, by switching to different independent reading states, the RFID tag 50 that has been missed can be read. As a result, even when the number of RFID tags 50 is large, the information of the RFID tags 50 can be reliably read without failing to be read.

Further, in the RFID tag reader 10 of the first embodiment, the trigger signal starts reading in the reading state specified by the reading state specifying section 62 (designating means), and then all the RFID tags 50 are read. This is a signal issued by the reading operation control section 65 (reading control means) when the first predetermined time t1 has elapsed without completion. Therefore, by switching the reading state at a predetermined time, it is possible to prevent the reading time from becoming long.

Further, in the RFID tag reader 10 of the first embodiment, the timer 64 sets the first predetermined time t1 according to the number N of RFID tags 50 . Therefore, reading can be completed in an appropriate time according to the number N of RFID tags 50 .

Further, in the RFID tag reader 10 of the first embodiment, the trigger signal is a signal issued by the reading operation control section 65 (reading control means) on condition that a predetermined operation instruction is received. Therefore, the reading state can be switched at any timing.

(Second embodiment)
Next, an RFID tag reader 10a (not shown) of the second embodiment will be described. The RFID tag reader 10a of the second embodiment detects that the information of the new RFID tag 50 is read by the second The read state of the RFID tag 50 is switched even when it is not read for the predetermined time t2. The hardware configuration and functional configuration of the RFID tag reader 10a of the second embodiment are substantially the same as those of the RFID tag reader 10 of the first embodiment. is omitted.

In the RFID tag reader 10a of the second embodiment, the reading operation control unit 65 (reading control means) controls the timing at which the first predetermined time t1 has elapsed since reading was started in a new session, and the timing at which reading is performed. A trigger signal is generated at the timing when new information on the RFID tag 50 is not read for the second predetermined time t2 and at the timing when the operator of the RFID tag reader 10 presses the recovery button 86. do.

(Explanation of user interface)
Next, a user interface for operating the RFID tag reader 10a of the second embodiment will be described with reference to FIG. FIG. 11 is a diagram showing an example of a user interface screen displayed when operating the RFID tag reader according to the second embodiment.

Before the RFID tag reader 10a starts operating, the display control unit 67 displays the same start screen G1 (FIG. 8(a)) as in the first embodiment on the display operation device 18 (display device 18a). .

When the setting button 83 is pressed on the start screen G1, the display control unit 67 displays the setting screen G4 shown in FIG. 11 on the display operation device 18 (display device 18a).

The setting screen G4 is a screen for setting a session transition state (recovery mode), a first predetermined time t1, and a second predetermined time t2.

The second predetermined time t2 can be set for each session. The second predetermined time t2 is set separately for sessions other than the final session (sessions S2/S3 in the example of FIG. 11) and the final session (sessions S0/S1 in the example of FIG. 11) designated as the recovery mode. be able to.

That is, the RFID tag reader 10 can separately set the second predetermined time t2a for sessions other than the final session and the second predetermined time t2b for the final session.

For example, in sessions other than the last, by setting the second predetermined time t2a short, if the information of the new RFID tag 50 cannot be read, the session is switched to the next session. can be shortened. Also, the second predetermined time t2b in the final session may be set longer than the second predetermined time t2a in consideration of safety.

The second predetermined time t2 depends on the number N of RFID tags 50, but is set to t2a=10 s, t2b=20 s, etc., when switching from session S2_A to session S3_A. When switching from session S2_A to session S1_A, for example, t2a=10 s and t2b=30 s are set. Also, these second predetermined times t2 (t2a, t2b) may be calculated based on the number N of RFID tags 50. FIG.

FIG. 11 shows that since session S2→S1 is selected as the recovery mode, the second predetermined time t2 can be set only for the portions related to session S2 and session S1. there is In other words, portions that are not involved in the recovery mode are displayed in a light color, and the second predetermined time t2 cannot be set. This prevents the operator from setting the wrong time.

Further, the RFID tag reader 10a of the second embodiment can select whether to enable (ON) or disable (OFF) the automatic recovery function, as in the first embodiment. . FIG. 11 shows an example in which the automatic recovery function is set to ON.

(Flow of processing performed by RFID tag reader)
Next, the flow of processing performed by the RFID tag reader 10a will be described with reference to FIG. FIG. 12 is a flow chart showing an example of the flow of reading processing performed by the RFID tag reader of the second embodiment. FIG. 12 shows, as an example, the flow of processing when transitioning from the reading state T11 to the reading state T12. FIG. 12 shows the flow of processing when the settings shown in FIG. 11 are made on the setting screen G4. For the sake of simplicity, FIG. 12 omits the process of switching sessions when the operator of the RFID tag reader 10a presses the recovery button 86. FIG.

The tag quantity acquisition unit 61 acquires the quantity N of the RFID tags 50 (step S31).

The timer 64 sets the first predetermined time t1 and the second predetermined times t2a and t2b (step S32). Note that the first predetermined time t1 and the second predetermined times t2a and t2b are set according to the values input to the setting screen G4. Also, the first predetermined time t1 may be calculated by the timer 64 based on the number N of RFID tags 50 .

The timer 64 resets the elapsed times ta and tb (step S33). The elapsed time ta represents the elapsed time from the start of the session, and is the time used for evaluating whether the elapsed time ta exceeds the first predetermined time t1. Also, the elapsed time tb represents the elapsed time after reading a new RFID tag 50, and is the time used for evaluating whether the elapsed time tb exceeds the second predetermined times t2a and t2b.

The reading state designation unit 62 designates the reading state as session S2_A (or S3_A), that is, the first reading state, and the signal reading unit 63 reads the reflected wave of the radio wave irradiated to the RFID tag 50 (step S34). .

The signal reading unit 63 determines whether information on the new tag has been read (step S35). If it is determined that the information of the new tag has been read (step S35: Yes), the process proceeds to step S36. On the other hand, if it is not determined that the information of the new tag has been read (step S35: No), the process proceeds to step S37.

If determined as Yes in step S35, the signal reading unit 63 determines whether all RFID tags 50 have been read (step S36). When it is determined that all the RFID tags 50 have been read (step S36: Yes), the RFID tag reader 10a ends the processing of FIG. On the other hand, if it is not determined that all the RFID tags 50 have been read (step S36: No), the process proceeds to step S38.

On the other hand, if determined as No in step S35, the timer 64 determines whether the elapsed time tb is equal to or longer than the second predetermined time t2a (step S37). If it is determined that the elapsed time tb is equal to or longer than the second predetermined time t2a (step S37: Yes), the process proceeds to step S40. On the other hand, if it is determined that the elapsed time tb is not longer than the second predetermined time t2a (step S37: No), the process returns to step S34.

Returning to step S36, when the determination in step S36 is No, the timer 64 determines whether the elapsed time ta is equal to or greater than the first predetermined time t1 (step S38). If it is determined that the elapsed time ta is equal to or longer than the first predetermined time t1 (step S38: Yes), the process proceeds to step S40. On the other hand, if it is determined that the elapsed time ta is not longer than the first predetermined time t1 (step S38: No), the process returns to step S39.

If determined as Yes in step S38 or determined as Yes in step S37, the timer 64 resets the elapsed times ta and tb (step S40). At this time, the reading operation control section 65 outputs a trigger signal to the reading state designating section 62 .

Further, when the determination in step S38 is No, the timer 64 resets the elapsed time tb (step S39). After that, the process returns to step S34.

Following step S40, the reading state designating section 62 receives the trigger signal from the reading operation control section 65, designates the reading state as session S1_A (or S0_A), that is, the second reading state, and the signal reading section 63 reads the reflected wave of the radio wave irradiated to the RFID tag 50 (step S41).

The signal reading unit 63 determines whether information on the new tag has been read (step S42). If it is determined that the information of the new tag has been read (step S42: Yes), the process proceeds to step S43. On the other hand, if it is not determined that the information of the new tag has been read (step S42: No), the process proceeds to step S44.

If determined as Yes in step S42, the signal reading unit 63 determines whether all the RFID tags 50 have been read (step S43). When it is determined that all the RFID tags 50 have been read (step S43: Yes), the RFID tag reader 10a terminates the processing of FIG. On the other hand, if it is not determined that all the RFID tags 50 have been read (step S43: No), the process proceeds to step S45.

When determined as No in step S43, the timer 64 determines whether the elapsed time ta is equal to or longer than the first predetermined time t1 (step S45). When it is determined that the elapsed time ta is equal to or longer than the first predetermined time t1 (step S45: Yes), the RFID tag reader 10a terminates the processing of FIG. On the other hand, if it is determined that the elapsed time ta is not longer than the first predetermined time t1 (step S45: No), the process proceeds to step S46.

If determined as No in step S45, the timer 64 resets the elapsed time tb (step S46). After that, the process returns to step S41.

On the other hand, if determined as No in step S42, the timer 64 determines whether the elapsed time tb is equal to or longer than the second predetermined time t2b (step S44). When it is determined that the elapsed time tb is equal to or longer than the second predetermined time t2b (step S44: Yes), the RFID tag reader 10a terminates the processing of FIG. On the other hand, if it is determined that the elapsed time tb is not longer than the second predetermined time t2b (step S44: No), the process returns to step S41.

Note that when the RFID tag reader 10a changes the reading state from the reading state T11 to the reading state T13, and when it changes the reading state from the reading state T11 to the reading state T12 via the reading state T13, The flow is similar to that of FIG.

As described above, in the RFID tag reader 10a of the second embodiment, the trigger signal is generated when reading is being performed in the reading state designated by the reading state designating section 62 (designating means). This signal is issued by the reading operation control section 65 (reading control means) when the information on the tag 50 is not read for the second predetermined time t2 (t2a, t2b). Therefore, when new tag information is not read, the session can be switched immediately. This can prevent the reading time from becoming long.

Although the embodiment of the present invention has been described above, this embodiment is an example and is not intended to limit the scope of the invention. This novel embodiment can be embodied in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

10, 10a RFID tag reader (wireless tag reader)
42 Goods 50 RFID tag (wireless tag)
62 Reading state designation unit (designation means)
63 signal reading unit (reading means)
65 reading operation control unit (reading control means)
t1 first predetermined time t2, t2a, t2b second predetermined time

JP 2017-130885 A

Claims (4)

A wireless tag reader that reads information on a wireless tag,
reading means for reading information on the wireless tag;
The reading state by the reading means is such that after the reading means reads the response of the wireless tag, when the periodical power supply to the wireless tag is continued, the response from the wireless tag is kept within the first suppression time. a first reading state in which the response from the wireless tag is inhibited for a period of time; and after the reading unit reads the response from the wireless tag, regardless of whether or not power is supplied to the wireless tag, the response from the wireless tag is suppressed during the second suppression time. a second reading state in which the response from the wireless tag is inhibited over a period of time; a third reading state of inhibiting for a period of inhibition; and inhibiting a response from the wireless tag when power is continuously supplied to the wireless tag after the reader reads the response of the wireless tag. a specifying means for specifying any of the fourth reading state to
When reading is started in the reading state specified by the specifying means, and a first predetermined time set according to the number of the wireless tags has passed without completing the reading of all the wireless tags. and changing the reading state of the reading means from the first reading state or the third reading state to the second reading state or the fourth reading state, or the third reading state or the third reading state. reading control means for outputting a trigger signal for switching to reading state 1;
A wireless tag reader. The trigger signal is issued by the reading control means when information on a new wireless tag is not read for a second predetermined time during reading in the reading state specified by the specifying means. is a signal,
The wireless tag reader according to claim 1 . The trigger signal is a signal issued by the reading control means on condition that a predetermined operation instruction is received.
The wireless tag reader according to claim 1 or 2 . A computer that controls a wireless tag reader that reads wireless tag information,
reading means for reading information on the wireless tag;
The reading state by the reading means is such that after the reading means reads the response of the wireless tag, when the periodical power supply to the wireless tag is continued, the response from the wireless tag is kept within the first suppression time. a first reading state in which the response from the wireless tag is inhibited for a period of time; and after the reading unit reads the response from the wireless tag, regardless of whether or not power is supplied to the wireless tag, the response from the wireless tag is suppressed during the second suppression time. a second reading state in which the response from the wireless tag is inhibited over a period of time; a third reading state of inhibiting for a period of inhibition; and inhibiting a response from the wireless tag when power is continuously supplied to the wireless tag after the reader reads the response of the wireless tag. a specifying means for specifying any of the fourth reading state to
When reading is started in the reading state specified by the specifying means, and a first predetermined time set according to the number of the wireless tags has passed without completing the reading of all the wireless tags. and changing the reading state of the reading means from the first reading state or the third reading state to the second reading state or the fourth reading state, or the third reading state or the third reading state. reading control means for outputting a trigger signal for switching to reading state 1;
program to function as

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