JP2016058028A - Rfid tag and rfid tag system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an RFID tag and an RFID tag system, capable of completing radio communication performed between a reader/writer and the RFID tag in a short time when rewiring display contents of a display unit, and surely rewriting the display contents of the display unit even under a peripheral environment under which the radio communication tends to be unstable.SOLUTION: Base image data 22 and fixed-form image data 23 are stored in a storage unit 18. An image of the base image data 22 is provided with a composite area 25 identified by an area code. A fixed-form image code for identifying the fixed-form image data 23 is assigned to the fixed-form image data 23. A display controller 16 rewrites the display contents by displaying an image of display image data 21 generated by reading the base image data 22 and the fixed-form image data 23 from the storage unit 18 on the display unit 17 on the basis of a rewrite command. The rewrite command is configured to include the area code and the fixed-form image code.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an RFID tag including a display unit for displaying characters and images, and an RFID tag system, and in particular, an RFID tag in which radio waves used for wireless communication between the outside and the RFID tag are in the UHF frequency band, And an RFID tag system.

  An RFID tag including a display unit is known, for example, from Patent Document 1. In Patent Document 1, a non-contact IC card (RFID tag) with a display is configured by a non-contact IC chip, an antenna, a display module, and the like. The display module includes a display element (display unit), a display driver, a communication IC chip, a CPU, a memory, and the like. The communication IC chip communicates with the non-contact IC chip to read information, and the CPU generates display data from the read information and displays it on the display element. The non-contact IC card performs wireless communication using NFC (Near Field Communication) that performs communication in a state where the antenna of the non-contact IC chip and the antenna of the reader / writer on the terminal side are close to each other. ing.

  In the present invention, radio waves in the UHF frequency band are used for wireless communication between the reader / writer and the RFID tag. A similar RFID tag is disclosed in Patent Document 2, for example. In Patent Document 2, an RFID tag is configured by an antenna, an IC chip, and electronic paper (display unit) that is a display device. The IC chip includes a power generation unit, a demodulation unit, a modulation unit, a control unit, a storage unit, and the like.

JP 2010-257159 A JP 2010-218256 A

  In an RFID tag having a display unit, such as the non-contact IC card of Patent Document 1 and the RFID tag of Patent Document 2, by displaying information in the RFID tag, or arbitrary characters and images on the display unit, The function of the RFID tag and the function of the display body can be exhibited, and a multifunctional RFID tag can be obtained. However, when performing wireless communication between the non-contact IC card and the reader / writer of Patent Document 1, it is necessary to hold the reader / writer and the antenna of the IC card close to each other, and the rewriting operation is troublesome. In addition, when a large amount of data such as an image is transmitted from the reader / writer to the non-contact IC card, it is inevitable that the communication time becomes longer due to the larger amount of data, and the time for rewriting the display contents There is a protracted disadvantage.

  Since the RFID tag of Patent Document 2 performs wireless communication using the UHF frequency band, the communication distance can be increased compared to the case of performing wireless communication using NFC, and the reader / writer and the antenna of the RFID tag There is no need to keep them close together. However, if the communication distance is large, the state of wireless communication tends to become unstable due to the influence of the surrounding environment such as reflected waves of radio communication waves on the wall surface and obstacles. In particular, when a large amount of data such as an image is transmitted to the RFID tag, the communication time becomes long, so that the surrounding environment is likely to be disturbed until the communication is completed. For this reason, wireless communication becomes unstable during data transmission, and the display content of the display unit cannot easily be rewritten.

  An object of the present invention is to complete wireless communication performed between the outside and the RFID tag in a short time when rewriting the display content of the display unit in a surrounding environment in which wireless communication is likely to become unstable. However, an object of the present invention is to provide an RFID tag and an RFID tag system that can reliably rewrite the display content of the display unit.

  The present invention includes a communication controller 8 that performs wireless communication with the outside, a display unit 9, and a power source 10 that supplies power to both of them. The display unit 9 is connected to the communication controller 8. An RFID tag that includes a display controller 16, a display unit 17 composed of a non-volatile display medium, and a storage unit 18 that stores various data, and that performs radio communication with the outside using radio waves in the UHF frequency band as a communication medium. And The storage unit 18 stores base image data 22 and fixed image data 23. The image of the base image data 22 is provided with a synthesis area 25 that is specified by an area code and on which the standard image data 23 is superimposed. A fixed image code for specifying the fixed image data 23 is assigned to the fixed image data 23. The display controller 16 reads the base image data 22 and the fixed image data 23 from the storage unit 18 based on the rewrite command transmitted from the outside to the communication controller 8, and superimposes the base image data 22 and the fixed image data 23. After the display image data 21 is generated, an image of the generated display image data 21 is displayed on the display unit 17, and the display contents are rewritten. The rewrite command includes an area code for designating the image synthesis area 25 of the base image data 22 and a standard image code for designating the standard image data 23 to be superimposed on the synthesis area 25 designated by the area code. It is characterized by. Note that the “nonvolatile display medium” here refers to a display medium that consumes power at the time of rewriting the display and can maintain the display state without consuming power after the rewriting of the display or with very little power consumption. For example, there are electronic paper and an organic EL display having advantages similar to those of electronic paper that is still under development.

  The communication controller 8 changes the mode between a communication mode for performing wireless communication with the outside using the power of the power supply 10 and a standby mode for receiving and waiting for a transmission wave from the outside without using the power of the power supply 10. Configure as possible. The display unit 9 uses the power of the power supply 10 to rewrite the display content of the display unit 17, and uses the slight power of the power supply 10 to sleep and receive the activation signal from the communication controller 8. The mode can be changed. As the communication controller 8 changes the mode from the standby mode to the communication mode, the display unit 9 changes the mode from the sleep mode to the rewrite mode, and the display unit 9 changes the mode from the rewrite mode to the sleep mode. Accordingly, the communication controller 8 is configured to change the mode from the communication mode to the standby mode.

  A plurality of base image data 22 is stored in the storage unit 18, and a base image code for specifying the base image data 22 is assigned to each base image data 22. The rewrite command is configured to include a base image code for designating the base image data 22.

  The RFID tag has an update mode in which data in the storage unit 18 is rewritten. In the update mode, after erasing a part or all of the base image data 22 and the fixed image data 23 stored in the storage unit 18, the RFID tag The base image data 22 and the fixed image data 23 transmitted to the communication controller 8 are stored in the storage unit 18.

  The form which comprises the display part 17 with electronic paper can be taken.

  The present invention is also directed to an RFID tag system including the RFID tag described above, the host terminal 1, and the reader / writer 2 that is controlled by the host terminal 1 and performs wireless communication with the RFID tag. A plurality of gates 31 are provided at different positions facing the conveyance path 30 of the conveyance body 5 to which the RFID tag is attached, and the reader / writer 2 is disposed at each gate 31. When the carrier 5 passes through the gate 31, wireless communication is performed between the reader / writer 2 and the RFID tag, and the display content of the display unit 17 is rewritten.

  In the RFID tag and RFID tag system of the present invention, the base image data 22 and the fixed image data 23 are stored in the storage unit 18. The base image data 22 is provided with a synthesis area 25 on which the standard image data 23 specified by the area code is superimposed. A fixed image code for specifying the standard image data 23 is assigned to the standard image data 23. It was. Further, the display controller 16 reads the base image data 22 and the standard image data 23 from the storage unit 18 based on the rewrite command transmitted from the outside to the communication controller 8, and superimposes the base image data 22 and the standard image data 23. Then, after generating the display image data 21, the image of the generated display image data 21 is displayed on the display unit 17, and the display content is rewritten. The rewrite command includes an area code for specifying the image synthesis area 25 of the base image data 22 and a standard image code for specifying the standard image data 23 to be superimposed on the synthesis area 25 specified by the area code. .

  As described above, if the base image data 22 and the fixed image data 23 are stored in the storage unit 18 in advance, it is not necessary to transmit image data having a large capacity from the outside to the RFID tag, and the area code and the fixed image code are stored. The display controller 16 generates the display image data 21 just by transmitting a rewrite command with a small capacity composed of, for example, to the RFID tag, and displays the image of the generated display image data 21 on the display unit 17. Display contents can be rewritten. Accordingly, for example, even in an environment such as a factory or warehouse where there are many obstacles and wireless communication is likely to be unstable, wireless communication with the RFID tag is completed in a short time, and the display unit 17 is surely provided. The display content of can be rewritten. In addition, since different display image data 21 can be generated by changing the fixed image data 23 to be superimposed on the synthesis area 25, various display contents can be displayed on the display unit 17.

  The communication controller 8 can change the mode between a communication mode in which wireless communication is performed with the outside using the power of the power supply 10 and a standby mode in which a transmission wave from the outside is received without using the power of the power supply 10. Configured. Further, the mode is changed to a rewrite mode in which the display content of the display unit 17 is rewritten using the power of the power source, and a sleep mode in which a small amount of power from the power source 10 is used to receive and wait for an activation signal from the communication controller 8. The display unit 9 was configured as possible. In addition, as the communication controller 8 changes the mode from the standby mode to the communication mode, the display unit 9 changes the mode from the sleep mode to the rewrite mode, and the display unit 9 changes the mode from the rewrite mode to the sleep mode. Accordingly, the communication controller 8 changes the mode from the communication mode to the standby mode. According to this, the power consumption of the power source 10 is hardly used except during the rewriting operation of the display unit 17, and the power consumption of the power source 10 can be reduced. Therefore, it is possible to reduce labor and time required for maintenance of the RFID tag by reducing the frequency of power supply replacement of the RFID tag. In addition, since the power of the power supply 10 is used during the rewriting operation of the display unit 17, the display contents of the display unit 17 can be rewritten with certainty by operating the communication controller 8 and the display unit 9 accurately.

  When a plurality of base image data 22 is stored in the storage unit 18, a base image code is assigned to each base image data 22, and a rewrite command includes a base image code that designates the base image data 22, it should be displayed. By increasing the types of images of the base image data 22, the display content of the display unit 17 can be rewritten in various ways.

  The RFID tag has an update mode in which data in the storage unit 18 is rewritten. In the update mode, after erasing a part or all of the base image data 22 and the fixed image data 23 stored in the storage unit 18, the RFID tag The base image data 22 and the fixed image data 23 transmitted from the communication controller to the communication controller are stored in the storage unit 18. According to this, the optimum display image data 21 corresponding to the place where the RFID tag is used is generated by setting the RFID tag in the update mode and storing the desired base image data 22 and the fixed image data 23 in the storage unit 18. The RFID tag is easy to use.

  Electronic paper, for example, consumes less power when rewriting display content than a liquid crystal display, and can maintain a display state without consuming power. Therefore, according to the RFID tag in which the display unit 17 is made of electronic paper, the power consumption of the power source 10 in the display unit 17 can be further reduced, and the life of the power source 10 can be extended.

  In an RFID tag system including the RFID tag, the host terminal 1, and a reader / writer 2 that is controlled by the host terminal 1 and performs wireless communication with the RFID tag, the conveyance path 30 of the carrier 5 to which the RFID tag is attached is provided. A plurality of gates 31 are provided at different positions facing each other, and the reader / writer 2 is arranged at each gate 31. Then, when the carrier 5 passes through the gate 31, wireless communication is performed between the reader / writer 2 and the RFID tag, and the display content of the display unit 17 is rewritten. According to such an RFID tag system, the reader / writer 2 and the RFID tag perform wireless communication when passing through the gate of the carrier 5, so that the carrier 5 on which the RFID tag is mounted is conveyed to any position on the conveyance path 30. It can be confirmed by the host terminal 1. Further, for example, by displaying the next transport destination of the transport body 5 that has passed through the gate 31 on the display unit 17, the transport destination of the transport body 5 can be visually confirmed. In the RFID tag system of the present invention, since the wireless communication between the reader / writer 2 and the RFID tag can be completed in a short time, even if the RFID tag is moving on the conveyance path 30, the display unit Since the display content of 17 can be rewritten, it is suitable as an RFID tag system for performing wireless communication between the reader / writer 2 and the RFID tag attached to the moving carrier 5.

It is a block diagram which shows the RFID tag which concerns on this invention, a host terminal, and a reader / writer. It is the perspective view which shows the state which mounted | wore the component stocker with the RFID tag, and the front view of a RFID tag. It is the sectional view on the AA line in FIG. 2, and the BB line arrow view in FIG. It is a front view which shows an example of the display content of a display part. It is explanatory drawing which shows an example of the image of the base image data stored in the memory | storage part, and the image of fixed form image data. It is a flowchart which shows the operation | movement flow of a host terminal and an RFID tag. It is explanatory drawing of the RFID tag system which concerns on this invention.

(Example) FIGS. 1-7 shows the Example of the RFID tag system based on this invention. In the present embodiment, front and rear, left and right, and up and down follow the arrows shown in FIG. In FIG. 1, the RFID tag system includes an RFID tag, a host terminal 1 composed of a personal computer (PC), a plurality of reader / writers 2 connected to the host terminal 1, and the like. And reader / writer 2 perform non-contact wireless communication. For this wireless communication, radio waves in the UHF frequency band (920 MHz) are used, and communication control based on “EPC Global Class-1 Generation-2” is performed. The reader / writer 2 is controlled by the host terminal 1 and includes an antenna 3 that transmits a transmission wave for wireless communication or receives a reflected wave from an RFID tag. The antenna 3 is configured by a patch antenna.

  As shown in FIG. 2, the RFID tag includes a tag main body 7 that is attached to the outside of the side wall of a square box-shaped component stocker (conveyance body) 5 that opens upward. As shown in FIG. 3, the tag body 7 includes a square box-shaped front case 7a having an opening on the rear surface and a rear case 7b fixed so as to close the rear surface opening of the front case 7a. 7b is made of an opaque resin. A window 7c is opened on the front surface of the front case 7a, and a protective cover 7d made of transparent resin is fitted into the window 7c. As shown in FIG. 1, a tag main body 7 includes a communication controller 8 that performs wireless communication with the reader / writer 2, a display unit 9, and a primary battery (power source) 10 that supplies power to both of them. Have The communication controller 8 includes an antenna 11 that receives a transmission wave for wireless communication from the reader / writer 2 or transmits a reflected wave. The antenna 11 is a folded dipole antenna. The communication controller 8 transmits data to the reader / writer 2 or communicates with the display unit 9 based on a command transmitted from the reader / writer 2. The communication controller 8, the antenna 11, the display unit 9, the primary battery 10, and the like are mounted on the substrate 12 (see FIG. 1). Details of the substrate 12 will be described later.

  The communication controller 8 includes a storage unit 14, and the storage area is divided into a system area and a user area. In the system area, an identification code unique to the communication controller 8 and a program for controlling wireless communication with the reader / writer 2 are provided, whereby the communication controller 8 has the function of an RFID tag alone. In the system area, a program for controlling communication with the display control 16 of the display unit 9 is stored. The user area is used for temporarily storing data transmitted from the reader / writer 2 when the communication controller 8 communicates with the display unit 9.

  The communication controller 8 waits to receive a transmission wave from the reader / writer 2 without using the communication mode for performing wireless communication with the reader / writer 2 using the power of the primary battery 10 and the power of the primary battery 10. The mode can be changed to the standby mode. As the power for changing the mode from the standby mode to the communication mode, the power generated by the radio wave when the antenna 11 receives the transmission wave radiated from the reader / writer 2 is used.

  The display unit 9 includes a display controller 16 connected to the communication controller 8, a display unit 17 made of electronic paper (nonvolatile display medium), and a storage unit 18 for storing various data. The display unit 17 is provided with its display surface facing the protective cover 7 d, and a display driver 19 is provided between the display controller 16 and the display unit 17. The display driver 19 controls display contents on the display unit 17 and deletes the display contents. The entire display unit 9 is controlled by the display controller 16, a rewrite mode in which the display content of the display unit 17 is rewritten using the power of the primary battery 10, and a communication controller using a slight power of the primary battery 10. 8 is configured to be able to change the mode to a sleep mode in which a start signal from 8 is received and waited.

  As shown in FIGS. 1 to 3, the board 12 includes an antenna board 12 a on which the communication controller 8 and the antenna 11 are mounted, and a main board 12 b on which the display controller 16, the storage unit 18, the display driver 19, and the like are mounted. Has been. The antenna substrate 12a is connected to the main substrate 12b by a pin header 12c, and the display unit 17 is connected to the main substrate 12b by a flexible cable 12d. As shown in FIG. 3, with the gap G1 provided between the antenna substrate 12a and the main substrate 12b, the two substrates 12a and 12b are arranged so as to overlap in the front-rear direction. In addition, in a state where a gap G2 is provided between the display unit 17 and the main board 12b, the two parts 12b and 17 are arranged so as to overlap in the front-rear direction. Thereby, the antenna substrate 12a and the display unit 17 are arranged adjacent to each other, and a gap G3 is provided between the antenna substrate 12a and the display unit 17. By arranging the antenna substrate 12a and the display unit 17 so as to be adjacent to each other, the tag main body 7 is formed to be asymmetric in the front view. The gap G1 is set smaller than the gap G2.

  The gap G1 is preferably set to 2 mm or more and 5 mm or less. When the gap G1 is less than 2 mm, the antenna 11 receives both the transmission wave radiated from the antenna 3 of the reader / writer 2 and the transmission wave radiated from the antenna 3 and reflected by the wiring pattern of the main board 12b. This is because wireless communication becomes unstable. The wiring pattern of the main board 12b is formed by etching copper foil. On the other hand, if the gap G1 exceeds 5 mm, the pin header 12c that connects the antenna board 12a and the main board 12b easily picks up noise in the surrounding environment, and wireless communication becomes unstable. Further, by providing the gap G3, it is possible to effectively prevent the antenna 11 from receiving the transmission wave reflected by the electrode provided in the display unit 17 made of electronic paper. Similarly, in order to prevent the influence of the display unit 17 in communication, it is desirable that the communication controller 8 mounted on the antenna substrate 12a is disposed at a position separated from the adjacent end of the display unit 17 by a distance G4. In this embodiment, the gap G1 between the antenna board 12a and the main board 12b is set to 2.5 mm, the gap G2 between the main board 12b and the display unit 17 is set to 7.5 mm, and the antenna board 12a and the display unit 17 are set. The gap G3 was set to 3.5 mm. Further, the distance G4 between the display unit 17 and the communication controller 8 in the front view is set to 18 mm (see FIG. 3). In addition, the tag body 7 has a front and rear thickness dimension set to 17 mm, a left and right width dimension set to 160 mm, and a vertical height dimension set to 95 mm.

  The storage unit 18 stores a plurality of base image data 22 serving as a basis for the display image data 21 and a plurality of fixed image data 23. In the present embodiment, the three base image data 22a to 22c (22) shown in FIG. 5A, the standard image data 23a (23) of three characters shown in FIG. The standard image data 23b (23) of twelve numbers and symbols shown in c) and the standard image data 23c (23) of two barcodes shown in FIG. Each base image data 22 is assigned a base image code for specifying the base image data 22, and each fixed image data 23 is assigned a fixed image code for specifying the fixed image data 23. These image codes are also stored in the storage unit 18 together with each image data and an area code described later.

  Various characters and symbols are displayed in advance on the image of the base image data 22. Also, the image of the base image data 22 is provided with a synthesis area 25 that is specified by the area code and on which the standard image data 23 is superimposed. By superimposing the standard image data 23 on the synthesis area 25, the display unit Display image data 21 to be displayed on the screen 17 is generated. As shown in FIG. 5A, the image of the base image data 22a displays “management number”, “process No.”, “quantity”, “input date / time”, or a square frame. Six synthetic areas 25a to 25f indicated by imaginary lines are set in advance at positions associated with the display. Note that characters and images that are different from the image of the base image data 22a are also displayed in the images of the base image data 22b and 22c. The base image data 22a to 22c is image data having the same number of pixels as the number of display pixels of the display unit 17, and performs black and white display at a preset coordinate position to display characters as described above.

  The RFID tag has an update mode in which data in the storage unit 18 is rewritten, and the base stored in the storage unit 18 is performed by performing wireless communication with the reader / writer 2 in a state where the RFID tag is in the update mode. After erasing part or all of the image data 22 and the fixed image data 23, the base image data 22 and the fixed image data 23 transmitted from the reader / writer 2 are stored in the storage unit 18. When erasing a part of the base image data 22 and the fixed image data 23, it is possible to select and delete the arbitrary base image data 22 and the fixed image data 23 on the host terminal 1 side. Accordingly, the wireless communication time in the update mode can be shortened compared to the case where all of the base image data 22 and the fixed image data 23 stored in the storage unit 18 are deleted. When data is rewritten in the storage unit 18 in the update mode, image data is transmitted from the reader / writer 2 to the RFID tag by wireless communication, so that the RFID tag is kept stationary in a surrounding environment that is hardly affected by disturbance. It is preferable. When the RFID tag is set to the update mode, the reader / writer 2 transmits a command for changing the tag to the update mode to the RFID tag. Alternatively, a mechanical switch may be provided to change the mode to the update mode. However, the former method is preferable because the structure of the RFID tag is not complicated and the operation of the switch is not required.

  The display controller 16 reads the base image data 22 and the standard image data 23 from the storage unit 18 based on the rewrite command transmitted from the reader / writer 2 to the communication controller 8, and superimposes the base image data 22 and the standard image data 23. Thus, display image data 21 is generated. After generating the display image data 21, the display controller 16 displays the generated display image data 21 on the display unit 17 and rewrites the display contents.

  The rewrite command designates a base image code for designating the base image data 22, an area code for designating the image synthesis area 25 of the base image data 22, and the standard image data 23 to be superimposed on the synthesis area 25 designated by the area code. It consists of a standard image code. As described above, according to the rewrite command composed of the code designating the base image data 22, the composite area 25, and the fixed image data 23, the data capacity can be reduced, and the display unit 17 can be rewritten. Wireless communication time can be shortened. The rewrite command transmitted from the reader / writer 2 is temporarily stored in the storage unit 14 of the communication controller 8, transferred to the display controller 16 through communication between the communication controller 8 and the display controller 16, and stored in the storage unit 18. The At this time, when data having a capacity larger than the user area of the storage unit 14 is transmitted from the reader / writer 2, the data is divided into a capacity that can be stored in the user area by the host terminal 1, and the data is transmitted to the communication controller 8 multiple times. It is transmitted and further transferred to the display controller 16. The same transmission control is performed when the image data is stored in the storage unit 18 in the RFID tag update mode described above.

  The contents of the rewrite command when the display controller 16 generates the image of the display image data 21 shown in FIG. 4 will be described. In the rewrite command in this case, a base image code for designating the base image data 22a shown in FIG. 5 is described at the head of the command. Next, an area code for designating the synthesis area 25a and “12000-56700-01” A plurality of standard image codes for designating each standard image data 23b of "" are described. Next, an area code for designating the composite area 25b and a plurality of standard image codes for specifying the standard image data 23b of “39-123” are described. Next, an area code for designating the composite area 25c and a plurality of standard image codes for designating each standard image data 23b of “150” are described. Next, an area code designating the composite area 25d and a plurality of standard image codes designating each standard image data 23b of “14/08/04” are described. Next, an area code for designating the composite area 25e and a standard image code for designating the standard image data 23a on which the characters “arrival” are drawn are described. Finally, an area code for specifying the synthesis area 25f and a fixed image code for specifying the fixed image data 23c of the two-dimensional barcode are described.

  Here, the communication time is compared between when the display image data 21 generated by the host terminal 1 is transmitted from the reader / writer 2 to the RFID tag and when the rewrite command according to the present embodiment is transmitted. First, for example, when the display unit 17 is made of 4.2-inch electronic paper and the number of display pixels is 400 × 300, the data amount of the display image data 21 shown in FIG. 4 generated by the host terminal 1 is 117 kbit. It was. When this is transmitted by communication control based on “EPC Global Class-1 Generation-2”, since the redundancy is about 6 times, the transmission data amount from the reader / writer 2 to the communication controller 8 is 702 kbit. Since the communication rate in the UHF frequency band of 920 MHz is 39 kbps, the communication time required for transmitting the display image data 21 generated by the host terminal 1 is about 18 seconds. In addition, when the display image data 21 is compressed, the data amount can be reduced to 39 kbits, but even in this case, a communication time of about 6 seconds is required. Next, the data amount of the rewrite command described above was 0.47 kbit. When this is transmitted by the same communication control, the amount of data is 2.81 kbit, so the communication time required for transmitting the rewrite command is about 0.07 seconds. Therefore, when the rewrite command is transmitted and the display on the display unit 17 is rewritten as in the present invention, the communication time can be remarkably shortened compared to the case of transmitting the image data. Note that the communication time calculated above does not include the response waiting time when the reader / writer 2 and the RFID tag perform wireless communication, and the internal processing time of the RFID tag.

  A process of generating the display image data 21 shown in FIG. 4 by the display controller 16 will be described. Based on the rewrite command, the display controller 16 first reads the base image data 22a specified by the base image code from the storage unit 18. Next, the process of reading and superimposing the designated fixed image data 23 from the storage unit 18 is repeated for each of the synthesis areas 25a to 25f. Thereby, the display image data 21 is generated.

  The flow of the rewriting operation of the display content on the display unit 17 will be described with reference to the flowchart of FIG. First, the display image data 21 is determined by the host terminal 1 and a rewrite command is generated. When the host terminal 1 is operated to start the rewrite operation, the host terminal 1 controls the reader / writer 2 to start transmitting a transmission wave, and transmits a rewrite command to the communication controller 8 (S1). At this time, the communication controller 8 is activated by the power generated by the radio wave when the antenna 11 receives the transmission wave radiated from the reader / writer 2, and the mode is changed from the standby mode to the communication mode (S2). Accordingly, the mode of the display unit 9 is changed from the sleep mode to the rewrite mode (S3). The communication controller 8 that has confirmed the mode change of the communication controller 8 and the display unit 9 transmits an activation confirmation signal including the identification code of the RFID tag to the reader / writer 2 (S4). The host terminal 1 that has confirmed the activation of the RFID tag (S5) starts transmission of the data of the rewrite command (S6). The communication controller 8 that has received the data temporarily stores the received data in the storage unit 14 (S7), and transfers the data to the display controller 16 (S8). The display controller 16 (S9) that has acquired the data stores the data in the storage unit 18 (S10). At this time, when data having a larger capacity than the user area of the storage unit 14 is transmitted from the reader / writer 2, the data is transmitted to the communication controller 8 a plurality of times, and the operations from S6 to S10 are repeated.

  The display controller 16 that has acquired all the data of the rewrite command reads the base image data 22 and the standard image data 23 stored in the storage unit 18 based on the rewrite command (S11), and displays the display image data described above. Through the generation process 21, display image data 21 to be displayed on the display unit 17 is generated (S 12). The generated display image data 21 is transferred to the display driver 19 (S13). The display driver 19 converts the display image data 21 into a data format that can be displayed on the display unit 17 (S14), and then displays it on the current display unit 17. The displayed display image data 21 is deleted, the generated image of the display image data 21 is displayed on the display unit 17, and the display contents are rewritten (S15). When the display controller 16 receives a signal indicating that the display content has been rewritten from the display driver 19, the display unit 9 is changed to the sleep mode (S16). Accordingly, the communication controller 8 transmits a signal indicating completion of rewriting to the reader / writer 2 (S17), and the mode is changed from the communication mode to the standby mode (S18). When the host terminal 1 confirms the completion of the rewrite operation (S19), the host terminal 1 controls the reader / writer 2 to stop the transmission of the transmission wave. When the activation confirmation is performed in the sequential operation S5, if the identification code of the RFID tag included in the activation confirmation signal is different from the identification code of the RFID tag to be rewritten, the rewriting operation is interrupted and the display unit 9 The reader / writer 2 transmits a signal for setting the communication controller 8 to the sleep mode and setting the communication controller 8 to the standby mode. At this time, the host terminal 1 notifies that the rewriting operation has ended abnormally.

The RFID tag shown in FIGS. 1 to 6 can be implemented in the following form.
The tag main body 7 includes a communication controller 8 that performs wireless communication with the reader / writer 2, a display unit 9 that includes a display unit 17 made of electronic paper, and a power source 10 that supplies power to both 8 and 9. The RFID tag that performs radio communication with the reader / writer 2 using radio waves in the UHF frequency band as a communication medium is an object. The communication controller 8 includes an antenna 11 that receives a transmission wave radiated from the reader / writer 2, and the communication controller 8 and the antenna 11 are mounted on a substrate 12 disposed inside the tag body 7, and the display unit 17 is The antenna 11 is disposed on the front surface of the substrate 12, and the antenna 11 is disposed on the substrate 12 that is out of the projection surface of the display unit 17 in a front view of the RFID tag.

  In the front view of the RFID tag shown in FIG. 2, when the antenna 11 is arranged on the substrate 12 away from the projection plane of the display unit 17, the reader / writer is compared with the case where the antenna 11 is arranged in the projection plane of the display unit 17. The area where the transmission wave radiated from 2 is blocked by the display unit 17 can be made as small as possible. Therefore, the transmission wave radiated from the reader / writer 2 can be satisfactorily received by the antenna 11. The reason why the display unit 17 blocks the transmission wave is that the electrode for switching the display state of the display unit 17 made of electronic paper exhibits the function of a shield that blocks and reflects the transmission wave.

  The display unit 9 includes a display controller 16 connected to the communication controller 8 and a storage unit 18 for storing various data. The substrate 12 includes an antenna substrate 12a on which the communication controller 8 and the antenna 11 are mounted, and a display controller. 16 and the main board 12b on which the storage unit 18 is mounted, and the antenna board 12a can be arranged on the front surface of the main board 12b via the gap G1.

  If the antenna board 12a is arranged on the front surface of the main board 12b via the gap G1, the antenna 11 can be effectively prevented from receiving the transmission wave reflected by the wiring pattern arranged on the main board 12b. The transmission wave radiated from the writer 2 can be received better by the antenna 11. Further, it is not necessary to provide the antenna board 12a except for the wiring pattern for connecting the antenna 11 and the communication controller 8 and the wiring pattern for connecting the antenna board 12a and the main board 12b. It is possible to effectively prevent the transmission wave radiated from being reflected.

  The antenna board 12a and the display part 17 can take the form arrange | positioned so that it may adjoin through the clearance gap G3. When the antenna substrate 12a and the display unit 17 are arranged so as to be adjacent to each other via the gap G3, it is possible to effectively prevent the antenna 11 from receiving the transmission wave reflected by the electrode of the display unit 17, and the reader / writer The transmission wave radiated from 2 can be received even better by the antenna 11.

  As an application example of the RFID tag system of the present embodiment, a case where it is used for component management in a factory will be described. As shown in FIG. 7, a conveyor line (conveyance path) 30 for conveying a component stocker 5 to which an RFID tag is attached is provided between the component receiving department and the warehouse, and between the warehouse and the assembly line. 30 includes a first conveyor line 30a that connects the parts receiving department and the warehouse, and a second conveyor line 30b that connects the warehouse and the assembly line. A plurality of gates 31 are provided at different positions facing the conveyor line 30. Specifically, the gate 31 is provided in each of the upstream end and downstream end of the 1st conveyor line 30a and the 2nd conveyor line 30b. The gate 31 at the upstream end of the first conveyor line 30 a is disposed facing the conveyance start end of the first conveyor line 30 a, but the other gate 31 is provided on the conveyor line 30. Each gate 31 is provided with a reader / writer 2, and is connected to the host terminal 1.

  A client terminal 32 is provided between the reader / writer 2 disposed at the gate 31 at the upstream end of the first conveyor line 30 a and the host terminal 1. The client terminal 32 has a function similar to that of the host terminal 1 and can perform wireless communication with the RFID tag by controlling the reader / writer 2 below the client terminal 32. Thereby, it is not necessary for the worker in the parts receiving department to move to the installation location of the host terminal 1 and rewrite the display unit 17, and the RFID tag display unit 17 can be rewritten in the vicinity of the parts receiving department. . At the time of this rewriting, as shown in FIG. 4, the part management number, the process number using the part, the quantity of the parts put into the part stocker 5, the date and time of insertion, the characters “arrival”, etc. are displayed on the display unit 17. . When the display unit 17 is rewritten at the client terminal 32, the rewrite information is transferred to the host terminal 1 and managed by the host terminal 1 in a state where the identification code of the RFID tag and the display content are associated with each other. The

  When the rewriting of the display unit 17 of the RFID tag is completed, the parts stocker 5 is transferred to the warehouse through the first conveyor line 30a. The reader / writer 2 of the other gates 31 excluding the gate 31 at the upstream end of the first conveyor line 30a always sends a rewrite command, and when the conveyed component stocker 5 passes through the gate 31, the RFID tag The rewrite command is received and activated, and an activation confirmation signal is transmitted to the reader / writer 2. The activation confirmation signal includes an RFID tag identification code, whereby the host terminal 1 can identify the parts stocker 5 and can confirm that the received parts have been transported to the warehouse. The host terminal 1 that has identified the parts stocker 5 rewrites the characters “arrival” on the display unit 17 of the RFID tag to “storage” by the rewriting operation described above in order to store the parts stocker 5 in the warehouse. In the RFID tag system of this embodiment, wireless communication between the reader / writer 2 and the RFID tag can be completed in a short time, so that the component stocker 5 is transported on the conveyor line 30 and the RFID tag moves. Even in the state, the display content of the display unit 17 can be rewritten. After confirming that the rewriting is completed, the warehouse worker stores the parts stocker 5 in the warehouse.

  When shipping the parts stocker 5 stored in the warehouse, a shipping instruction is registered in the host terminal 1, and the worker places the parts stocker 5 on the second conveyor line 30b according to the shipping instruction. The placed parts stocker 5 is transported and passes through the gate 31 on the upstream side of the second conveyor line 30b, and when it passes, the same operation as in the previous storage is performed. Will be rewritten. At this time, if the parts stocker 5 different from the shipping instruction is placed on the second conveyor line 30b, the identification code of the RFID tag does not match the identification code of the RFID tag registered in the shipping instruction. It can be determined that the component stocker 5 has been placed on the second conveyor line 30b, and the second conveyor line 30b is stopped to stop the conveyance. In this case, the display unit 17 is not rewritten. The parts stocker 5 conveyed to the downstream side passes through the gate 31 on the downstream side of the second conveyor line 30b. At this time, the word “shipping” is deleted, and the parts stocker 5 arriving at the production line is After visually confirming the control number, supply the parts to the assembly line. When a warehouse and a parts inspection site are installed together and stored in the warehouse after parts inspection, the word “arrival” is rewritten to “inspection” to indicate that the part stocker 5 requires inspection work, Can be transported to the warehouse. In this case, the client terminal 32 and the reader / writer 2 may be provided at the parts inspection site, and after the inspection is completed, the word “inspection” is rewritten to “storage” and the parts stocker 5 is stored in the warehouse.

  As described above, the reader / writer 2 and the RFID tag perform wireless communication when passing through the gate 31 of the component stocker 5, thereby determining which position on the conveyor line 30 the component stocker 5 to which the RFID tag is attached is conveyed. It can be confirmed by the host terminal 1. In addition, the worker can visually confirm the product number and the number of components accommodated in the component stocker 5 or the transport destination of the component stocker 5.

  As described above, in the RFID tag of this embodiment, the base image data 22 and the plural types of fixed image data 23 are stored in the storage unit 18, and rewriting when the display image data 21 is generated by the display controller 16 is performed. Since the command includes an area code for designating the image synthesis area 25 of the base image data 22 and a standard image code for designating the standard image data 23 to be superimposed on the synthesis area 25 designated by the area code, Large image data does not need to be transmitted from the reader / writer 2 to the RFID tag, and only the rewrite command having a small capacity composed of an area code and a fixed image code is transmitted to the RFID tag. Display image data 21 is generated, and an image of the generated display image data 21 is displayed on the display unit 17. Shows, it is possible to rewrite the display content. Therefore, wireless communication between the reader / writer 2 and the RFID tag can be completed in a short time even in an environment such as a factory or warehouse where there are many obstacles and wireless communication is likely to be unstable. The display contents of the display unit 17 can be rewritten. In addition, since different display image data 21 can be generated by changing the fixed image data 23 to be superimposed on the synthesis area 25, various display contents can be displayed on the display unit 17.

  A communication mode for performing wireless communication with the reader / writer 2 using the power of the primary battery 10 and a standby mode for waiting to receive a transmission wave from the reader / writer 2 without using the power of the primary battery 10 The communication controller 8 is configured to be changeable, the rewriting mode is used to rewrite the display content of the display unit 17 using the power of the power supply, and the communication controller 8 is activated using the slight power from the primary battery 10. The display unit 9 is configured so that the mode can be changed to a sleep mode in which a signal is received and waited. In addition, as the communication controller 8 changes the mode from the standby mode to the communication mode, the display unit 9 changes the mode from the sleep mode to the rewrite mode, and the display unit 9 changes the mode from the rewrite mode to the sleep mode. Accordingly, since the communication controller 8 changes the mode from the communication mode to the standby mode, the power of the primary battery 10 is hardly used except during the rewriting operation of the display unit 17. It is possible to reduce power consumption. Therefore, it is possible to reduce labor and time required for maintenance of the RFID tag by reducing the frequency of power supply replacement of the RFID tag. Further, since the power of the primary battery 10 is used during the rewriting operation of the display unit 17, the display contents of the display unit 17 can be rewritten with certainty by operating the communication controller 8 and the display unit 9 accurately.

  A plurality of base image data 22 is stored in the storage unit 18, a base image code is assigned to each base image data 22, and a base image code for designating the base image data 22 is included in the rewrite command. By increasing the types of images of the power base image data 22, the display contents of the display unit 17 can be rewritten in various ways.

  The RFID tag has an update mode in which the data in the storage unit 18 is rewritten. In the update mode, the base image data 22 and the fixed image data 23 stored in the storage unit 18 are partially or entirely erased and then the reader Since the base image data 22 and the standard image data 23 transmitted from the writer 2 are stored in the storage unit 18, the RFID tag is set in the update mode, and the desired base image data 22 and the standard image data 23 are stored on the user side. By storing the data in the storage unit 18, it is possible to generate the optimal display image data 21 according to the place where the RFID tag is used, and to make the RFID tag easy to use.

  Electronic paper, for example, consumes less power when rewriting display content than a liquid crystal display, and can maintain a display state without consuming power. Therefore, according to the RFID tag in which the display unit 17 is made of electronic paper, the power consumption of the power source 10 in the display unit 17 can be further reduced, and the life of the power source 10 can be extended.

  In the RFID tag system including the RFID tag, the host terminal 1, and the reader / writer 2 that is controlled by the host terminal 1 and performs wireless communication with the RFID tag, the conveyor line 30 of the component stocker 5 to which the RFID tag is mounted is provided. A plurality of gates 31 are provided at different positions facing each other, and the reader / writer 2 is arranged at each gate 31. Then, when the parts stocker 5 passes through the gate 31, wireless communication is performed between the reader / writer 2 and the RFID tag, and the display content of the display unit 17 is rewritten. According to the RFID tag system of the present embodiment, the wireless communication between the reader / writer 2 and the RFID tag can be completed in a short time, so that the reader / writer 2 and the RFID tag mounted on the moving component stocker 5 can be connected. It is suitable as an RFID tag system for performing wireless communication with a mobile phone.

  In the above embodiment, the composite area 25 is set in the base image data 22 in advance. However, this is not necessary, and the XY coordinates of the display unit 17 for specifying the base point of the composite area 25 (the upper left end of the composite area 25) and the base point The number of pixels in the X and Y directions can be used as area data. In this case, the fixed image data 23 can be freely superimposed on the base image data 22, and various display contents can be displayed on the display unit 17. A plurality of characters such as “arrival”, “storage”, and “shipment” are displayed in advance on the image of the base image data 22, and the standard image data 23 of a round frame or a square frame is enclosed so as to surround one of these characters. May be superimposed and this may be used as a transport destination display. In this case, the total storage capacity of the fixed image data 23 can be reduced by reducing the number of fixed image data 23 stored in the storage unit 18.

  Although the display unit 17 is composed of one electronic paper, the display unit 17 may be composed of a plurality of electronic papers, and the display contents of all electronic papers or arbitrary electronic papers can be rewritten. In this case, a code for specifying electronic paper to be rewritten may be included in the rewrite command. The power source 10 may use a secondary battery instead of the primary battery, and the charging method of the secondary battery may be any contact type or non-contact type charging method. In the arrangement of the antenna substrate 12a, the main substrate 12b, and the display unit 17, the gap G1 is set smaller than the gap G2, but the gap G1 can be set larger than the gap G2. The antenna 11 may be any antenna that can receive a transmission wave from the reader / writer 2 or transmit a reflected wave, such as a half-wave dipole antenna or a patch antenna, in addition to the folded dipole antenna.

1 Host terminal 2 Reader / writer 5 Carrier (component stocker)
8 Communication controller 9 Display unit 10 Power supply (primary battery)
16 Display Controller 17 Display Unit 18 Storage Unit 21 Display Image Data 22 Base Image Data 23 Standard Image Data 25 Composition Area 30 Conveyance Path (Conveyor Line)
31 gate

Claims (6)

A communication controller (8) for performing wireless communication with the outside, a display unit (9), and a power source (10) for supplying power to both (8, 9),
The display unit (9) includes a display controller (16) connected to the communication controller (8), a display unit (17) made of a nonvolatile display medium, and a storage unit (18) for storing various data. And
An RFID tag that performs radio communication with the outside using radio waves in the UHF frequency band as a communication medium,
The storage unit (18) stores base image data (22) and fixed image data (23).
The image of the base image data (22) is provided with a synthesis area (25) that is specified by the area code and on which the standard image data (23) is superimposed.
A fixed image code for specifying the fixed image data (23) is assigned to the fixed image data (23).
Based on the rewrite command transmitted to the communication controller (8), the display controller (16) reads the base image data (22) and the standard image data (23) from the storage unit (18), and the base image data (22). And the standard image data (23) are superimposed to generate the display image data (21), and then the image of the generated display image data (21) is displayed on the display unit (17) to rewrite the display contents. And
The rewrite command specifies an area code for specifying the image synthesis area (25) of the base image data (22) and a standard image code for specifying the standard image data (23) to be superimposed on the synthesis area (25) specified by the area code. The RFID tag characterized by including these. The communication controller (8) receives and waits for a communication mode in which wireless communication is performed with the outside using the power of the power source (10) and a transmission wave from the outside without using the power of the power source (10). It is configured to be able to change mode to standby mode,
The display unit (9) uses the power of the power source (10) to rewrite the display content of the display unit (17) and the communication controller (8) using the slight power of the power source (10). It is configured to be able to change the mode to sleep mode that waits to receive the activation signal of
As the communication controller (8) changes the mode from the standby mode to the communication mode, the display unit (9) is changed from the sleep mode to the rewrite mode, and the display unit (9) is changed from the rewrite mode to the sleep mode. The RFID tag according to claim 1, wherein the mode of the communication controller (8) is changed from the communication mode to the standby mode in accordance with the mode change. A plurality of base image data (22) is stored in the storage unit (18),
Each base image data (22) is assigned a base image code for identifying the base image data (22).
The RFID tag according to claim 1 or 2, wherein the rewrite command includes a base image code for designating base image data (22). The RFID tag has an update mode in which data in the storage unit (18) is rewritten,
In the update mode, after erasing part or all of the base image data (22) and the fixed image data (23) stored in the storage unit (18), the base transmitted from the outside to the communication controller (8). The RFID tag according to any one of claims 1 to 3, wherein the image data (22) and the fixed image data (23) are stored in the storage unit (18).   The RFID tag according to any one of claims 1 to 4, wherein the display unit (17) is made of electronic paper. An RFID tag comprising: the RFID tag according to any one of claims 1 to 5; a host terminal (1); and a reader / writer (2) controlled by the host terminal (1) to perform wireless communication with the RFID tag. A system,
A plurality of gates (31) are provided at different positions facing the conveyance path (30) of the conveyance body (5) to which the RFID tag is attached, and a reader / writer (2) is arranged at each gate (31),
When the carrier (5) passes through the gate (31), wireless communication is performed between the reader / writer (2) and the RFID tag, and the display content of the display unit (17) is rewritten. RFID tag system.

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