JP2018185580A - Identification body and identification body equipped article with the same equipped to product - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize reading to an identification body being used alone without increasing the cost, if there is no IP chips in the structure.SOLUTION: The present invention includes: a base material 10 made of a magnetic material; and an antenna 20 deposited on one surface of the base material 10, the antenna presenting a resonance peak by facing metal across the base material 10.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an identification body capable of recognizing identification information using an antenna and an identification body-mounted article in which the identification information is attached to the article.

  In recent years, with the progress of the information society, information is recorded on labels and tags attached to products and the like, and products and the like are managed using the labels and tags. In information management using such a label or tag, a non-contact type IC label or non-contact type in which an IC chip capable of writing or reading information in a non-contact state is mounted on the label or tag. Discriminators using RFID technology such as type IC tags are rapidly spreading due to their excellent convenience.

The identification body using such RFID technology is not limited to the one on which the IC chip is mounted as described above, and has a plurality of antennas having different resonance peak frequencies, and a plurality of antennas without using the IC chip. A device that can recognize an ID by a combination of antennas is also considered. For example, the shape of the dielectric element and the capacitor element constituting the plurality of antennas may be different, or the shape and direction of the plurality of antennas may be different to change the resonance peak frequency for each of the plurality of antennas. Patent Documents 1 and 2 disclose techniques that allow IDs to be expressed in combination. If this technology is used, if the number of antennas is N, two information of “1” and “0” can be given depending on the presence / absence of one antenna, and there is no case where all antennas are not present. Thus, (2 ^N −1) IDs can be expressed in a recognizable manner, and the cost can be reduced by not using an IC chip.

  However, in the case where the IC chip is not mounted as disclosed in Patent Documents 1 and 2, since the IC chip does not have the anti-collision function that the IC chip normally has, when there are a plurality of tags in the reading range of the reader, A tag that is used by being affixed to an article to be managed cannot be identified from a tag that is not affixed to an article to be managed and is not used, and IDs are read from all tags. Therefore, there is a problem that the reading process becomes impossible or an unnecessary ID is read.

  Here, Non-Patent Document 1 discloses a technique that enables reading only with respect to a chipless tag to be read by scanning a beam used for reading. In this technology, the irradiation range of the transmitting antenna is narrowed, and the irradiation position is freely scanned by controlling the phase of the beam, etc., so that only the tag to be read is irradiated with the radio wave. Even when multiple tags exist in the reading range, a tag that is used by being affixed to a managed article is identified from a tag that is not affixed to a managed article and is not used Will be able to.

  Further, Patent Document 3 discloses a metal article with a wireless communication device that is operated by arranging an antenna portion and a ground portion so as to face each other through a substrate and short-circuiting or capacitively coupling the antenna portion and the ground portion. . If this technology is used, the ground part is provided on the surface opposite to the antenna part of the substrate, so that even if the article to be attached is a metal object, the coupling between the antenna part and the ground part is not broken. Non-contact communication is possible.

Japanese Patent Publication No. 7-80386 Special table 2008-503759 gazette Japanese Patent No. 5703777

Nemai Chandra Karmakar, et al., (2016) “Chipless Radio Frequency Identification Reader Signal Processing,” Hoboken, New Jergy: John Wiley and Sons, inc.

  However, in the technique disclosed in Non-Patent Document 1, an antenna with a narrowed irradiation range is generally large and expensive, and a phase control device necessary for scanning is also expensive, thereby leading to an expensive reader. There is a problem that it becomes a thing.

  In the technique disclosed in Patent Document 3, a short circuit unit, a power supply unit, and an IC chip are essential in addition to a substrate, an antenna unit, and a ground unit, and there are many components. Since it has a structure in a direction perpendicular to the ground, the processing difficulty is high, and there is a problem that the price of the tag becomes expensive.

  The present invention has been made in view of the problems of the conventional techniques as described above, and has an expensive configuration for reading only the identifier used, even if it has no IC chip. It is an object of the present invention to provide an identification body that can be realized without performing it and an identification body-mounted article in which the identification body is attached to the article.

In order to achieve the above object, the present invention provides:
A base substrate comprising a magnetic material;
An antenna that is laminated on one surface of the base substrate and that exhibits a resonance peak by facing the metal through the base substrate.

  In the present invention configured as described above, a resonance peak appears when the antenna faces a metal, and identification information is recognized when this resonance peak is detected. Since the base material is laminated on one surface of the base material configured to include the body material, the base material can be attached to the region having the metal of the article to be managed, whereby the antenna is The material is in a state of facing the metal through the material, a resonance peak appears, and the identification information is recognized by detecting this resonance peak. As described above, since the resonance peak appears only in the identification object attached to the article simply by attaching the identification object to the article that is a management object having metal, the structure without the IC chip is used. Even if it exists, the reading only with respect to the identification body currently used is implement | achieved without setting it as an expensive structure.

  When the Q value in a state where the antenna is not opposed to the metal is 30 or less, the antenna can be attached to an article to develop a sharp resonance peak having a Q value of 30 or more.

  Further, as described above, the identification body is attached to the article as a form in which the identification body is attached to the article, and the article is attached to the article with the surface opposite to the antenna of the base substrate as the attachment surface. A region having a metal that covers the antenna in a plan view can be considered.

  According to the present invention, a resonance peak appears only in the identification object attached to the article simply by attaching the identification object to the article that is a management object having metal, and thus does not have an IC chip. Even if it is a structure, the reading only with respect to the identification object currently used can be implement | achieved, without making an expensive structure.

  In addition, when the antenna has a Q value of 30 or less when not facing a metal, a sharp resonance peak with a Q value of 30 or more can be exhibited by being attached to an article.

It is a figure which shows one Embodiment of the identification body of this invention, (a) is a figure which shows the structure of the surface, (b) is A-A 'sectional drawing shown to (a). It is a side view which shows an example of the identification body mounting article | item to which the ID tag shown in FIG. 1 is attached. It is a figure for demonstrating the characteristic of the ID tag shown in FIG.1 and FIG.2, and a tag mounting article, (a) is a figure which shows the frequency characteristic of an ID tag single-piece | unit, (b) is the ID tag 1 in a tag mounting article. It is a figure which shows the frequency characteristic. It is a figure which shows the application example of the ID tag shown in FIG. 1, (a) is a figure which shows the structure of the surface, (b) is A-A 'sectional drawing shown to (a). It is a figure which shows an example of the ID recognition system which recognizes ID provided to the ID tag shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings.

  1A and 1B are diagrams showing an embodiment of the discriminator of the present invention, in which FIG. 1A is a diagram showing the structure of the surface, and FIG. 1B is a cross-sectional view along A-A ′ shown in FIG.

  As shown in FIG. 1, the identification body in this embodiment is an ID tag 1 in which an antenna region 21 is provided on the surface of a base substrate 10 and a conductive antenna 20 is laminated on the antenna region 21.

  As the base substrate 10, for example, a sheet having a thickness of about 800 μm and a mixture of a resin and a magnetic material can be used. Examples of the magnetic material include sendust, carbonyl iron, and permalloy. The material is not limited to a mixture of resin and magnetic material, but may be a single magnetic material.

The antenna 20 is made of aluminum having a rectangular shape and a thickness of 80 μm, for example. The antenna 20 exhibits a resonance peak at a frequency corresponding to the shape of the antenna 20 by facing the metal. In order to develop a resonance peak when facing the metal, the Q value in the state where the antenna 20 alone, that is, the antenna 20 is not facing the metal is 30 or less, preferably 20 or less, or The antenna alone needs to have no resonance peak. This is because, when the antenna alone has a Q value of more than 30, the resonance peak does not appear when facing the metal, whereas when the antenna alone has a Q value of 30 or less, when facing the metal, the Q This is because a sharp resonance peak having a value of 30 or more appears. The Q value is the frequency at the resonance peak at ω ₀ , the frequency at which the vibration energy is half the resonance peak at the lower frequency side than the resonance peak is ω _1, and at the higher frequency side from the resonance peak. When the frequency at which the vibration energy is half the resonance peak is ω ₂ , this is a value represented by Q = ω ₀ / (ω ₂ −ω ₁ ).

  FIG. 2 is a side view showing an example of an identifier-equipped article to which the ID tag 1 shown in FIG. 1 is attached.

  For example, as shown in FIG. 2, the identifier-mounted article of the present invention can be configured as a tag-mounted article 2 configured by attaching the ID tag 1 shown in FIG. 1 to the article 3.

  In that case, the article 3 is made of metal and has a shape that covers the antenna 20 in plan view. The ID tag 1 is attached to the article 3 with the surface of the base substrate 10 opposite to the antenna 20 as the attachment surface. At that time, since the base substrate 10 is configured to include a magnetic material, the ID tag 1 can be easily attached to the article by adsorbing the ID tag 1 to the article 3 by the base substrate 10. . Further, when the ID tag 1 is removed from the article 3, no dirt such as an adhesive remains on the article 3 side.

  Below, the characteristic of ID tag 1 and tag mounting article 2 mentioned above is explained.

  FIG. 3 is a diagram for explaining the characteristics of the ID tag 1 and the tag-mounted article 2 shown in FIGS. 1 and 2, wherein (a) shows the frequency characteristics of the ID tag 1 alone, and (b) It is a figure which shows the frequency characteristic of ID tag 1 in the tag mounting goods 2. FIG.

  In the frequency characteristics of the single ID tag 1 shown in FIG. 1, as shown in FIG. 3A, the resonance peak due to the antenna 20 is not observed, and the single ID tag 1 does not function as a tag.

  On the other hand, when an SUS plate (stainless steel) having a thickness of 1 mm is used as the article 3 in the tag-mounted article 2 shown in FIG. 2, and the ID tag 1 is attached to the SUS board, the frequency characteristics thereof are shown in FIG. As shown, a resonance peak due to the antenna 20 appears and is observed.

  In this way, in the ID tag 1 shown in FIG. 1, since the antenna 20 faces the metal, a resonance peak appears at a frequency corresponding to the shape of the antenna 20, so that the ID tag as shown in FIG. 1 is attached to an article 3 made of metal so that the antenna 20 and the metal face each other, and electromagnetic waves are irradiated in that state. In the reflected wave, a resonance peak is detected in the vicinity of the frequency corresponding to the shape of the antenna 20. Depending on whether or not, the ID assigned to the ID tag 1 can be recognized. Specifically, since the resonance peak is detected if the antenna 20 is formed in the antenna region 21, the ID at that time is set to “1”, and if the antenna 20 is not formed in the antenna region 21, the resonance is detected. Since no peak is detected, the ID can be recognized by setting the ID at that time to “0”.

  Moreover, since the resonance peak is not detected because the unused ID tag 1 is not attached to the article 3, the ID tag that is used and the ID tag that is not used are determined depending on whether or not the resonance peak is detected. And can be identified.

  As described above, since the resonance peak appears only in the ID tag 1 attached to the article 3 simply by attaching the ID tag 1 to the article 3 made of metal, the structure has no IC chip. However, it is possible to read only the ID tag 1 being used without using an expensive configuration such as adding a special function to the reader side.

  The article 3 to which the ID tag 1 is attached is not limited to the one made of metal as described above, but only the region to which the ID tag 1 is attached is a metal that covers the antenna 20 in plan view. The region where the ID tag 1 is attached has a shape that covers the antenna 20 in plan view in the region where the ID tag 1 is attached, such as a case where a metal plate having a shape covering the antenna 20 in plan view is attached. Any metal can be used as long as it has a metal, including a metal.

  Here, according to what is disclosed in Patent Document 3, the conventional metal-compatible tag does not become an antenna in the first place when the connection between the antenna and the ground is weak. In order to radiate energy at the resonance point of the antenna, The connection reliability between the antenna and the ground is important. Therefore, the focus has been on how to ensure the connection reliability. In the tag-mounted article 2 shown in FIG. 2, the metal that is basically the ground is the reflection (radiation) surface, and the trough-shaped peak is expressed by the antenna absorbing energy at the resonance point. This is made to function as an ID. In this case, the ground metal and the antenna need only be capacitively coupled, and the connection reliability is not as high as that of the conventional metal-compatible tag. Therefore, the article 3 made of metal can be used as a ground as it is without providing a ground in advance.

  Hereinafter, an application example of the ID tag 1 shown in FIG. 1 will be described.

  4A and 4B are diagrams showing an application example of the ID tag 1 shown in FIG. 1, wherein FIG. 4A is a diagram showing a surface configuration, and FIG. 4B is a cross-sectional view taken along line AA ′ shown in FIG. .

  As shown in FIG. 4, the identification body in this application example is an ID tag 101 having five antenna regions 121a to 121e on the surface of a base substrate 110 similar to the base substrate 10 shown in FIG.

  Different frequencies are assigned to the antenna regions 121a to 121e. In this application example, a frequency of 7.0 GHz is assigned to the antenna region 121a, a frequency of 8.0 GHz is assigned to the antenna region 121b, and a frequency of 9.0 GHz is assigned to the antenna region 121c. A frequency is assigned, a frequency of 10.0 GHz is assigned to the antenna area 121d, and a frequency of 11.0 GHz is assigned to the antenna area 121e.

  In the antenna region 121a, an antenna 120a that exhibits a resonance peak in the vicinity of 7.0 GHz assigned to the antenna region 121a is formed by facing the metal via the base substrate 110. In the antenna region 121b, an antenna 120b that exhibits a resonance peak in the vicinity of 8.0 GHz assigned to the antenna region 121b is formed by facing the metal through the base substrate 110. In the antenna region 121c, an antenna 120c is formed that exhibits a resonance peak in the vicinity of 9.0 GHz assigned to the antenna region 121c by facing the metal through the base substrate 110. An antenna is not formed in the antenna region 121d. In the antenna region 121e, an antenna 120e is formed that exhibits a resonance peak in the vicinity of 11.0 GHz assigned to the antenna region 121e by facing the metal through the base substrate 110. The antennas formed in these antenna regions 121a to 121e have the same width and different lengths in the longitudinal direction, so that resonance peaks appear at different frequencies by facing the metal. ing. Among the antenna regions 121a to 121e, the antennas formed in the antenna regions 121a, 121b, 121d, and 121e have the same longitudinal direction, whereas the antenna 120c formed in the antenna region 121c The longitudinal direction is orthogonal to these and becomes a reference antenna. As described above, the antenna formed in the antenna regions 121a, 121b, 121d, and 121e and the antenna 120c formed in the antenna region 121c are different in polarization direction from each other because the longitudinal directions are orthogonal to each other. The antennas formed in the antenna regions 121a to 121e have the same width and different longitudinal lengths, so that resonance peaks appear at different frequencies by facing the metal. However, the resonance peaks may appear at different frequencies by making the widths of the antennas different from each other.

  FIG. 5 is a diagram illustrating an example of an ID recognition system that recognizes an ID assigned to the ID tag 101 illustrated in FIG. 4.

  As shown in FIG. 5, the ID recognition system in this example includes the ID tag 101 shown in FIG. 4 and a reader 50 that recognizes the ID assigned to the ID tag 101. The reader 50 includes a transmission antenna 51a. A reception antenna 51b, a transmission unit 52, a reception unit 53, a processing unit 54, and a control unit 55.

  The transmission unit 52 generates an electromagnetic wave including a frequency assigned to the antenna regions 121a to 121e, and irradiates it through the transmission antenna 51a.

  The receiving unit 53 receives the reflected wave from the ID tag 101 with respect to the electromagnetic wave irradiated from the transmitting unit 52 via the transmitting antenna 51a via the receiving antenna 51b, and detects the level of the received power of the reflected wave.

  The processing unit 54 detects the resonance peak in the ID tag 101 based on the level of received power detected by the reception unit 53, and the frequency at which the resonance peak is detected among the frequencies assigned to the antenna regions 121a to 121e. The ID is set to “1”, the ID for the frequency at which no resonance peak is detected is set to “0”, and these “1” and “0” are arranged in the order of frequencies to be given to the ID tag 101. Recognized ID is recognized. At this time, since the antenna 120c formed in the antenna region 121c has a polarization direction different from that of the antenna formed in the antenna regions 121a, 121b, 121d, and 121e as described above, the antenna 120c is used as a reference antenna. Use.

  The control unit 55 controls the irradiation of electromagnetic waves in the transmission unit 52 and each process in the processing unit 54.

  When the ID assigned to the ID tag 101 is recognized using the reader 50 configured as described above, the transmission unit 52 includes 7.0 GHz to 11.0 GHz allocated to the antenna regions 121 a to 121 e. While sweeping the frequency band, the electromagnetic wave of the frequency band is irradiated to the ID tag 101 attached to the article 3 made of metal like the ID tag 1 shown in FIG. 2 via the transmission antenna 51a.

  Then, the reflected wave from the ID tag 101 attached to the article 3 made of metal is received by the receiving unit 53 through the receiving antenna 51b, and the level of the received power of the reflected wave is detected. In the processing unit 54, A resonance peak is detected based on the level of received power detected by the receiving unit 53. In the ID tag 101 shown in FIG. 4, as described above, the antenna 120a having a resonance peak in the vicinity of 7.0 GHz is formed in the antenna region 121a by attaching the ID tag 101 to an article made of metal. In addition, the antenna 120b having a resonance peak in the vicinity of 8.0 GHz is formed in the antenna region 121b by attaching the ID tag 101 to an article made of metal, and the ID tag 101 is metal in the antenna region 121c. The antenna 120c having a resonance peak in the vicinity of 9.0 GHz is formed by being attached to the article made of, and the ID tag 101 is attached to the article made of metal in the antenna region 121e to be near 11.0 GHz. As a result, the antenna 120e having a resonance peak is formed. Received power of the reflected wave received by the receiver 53 comes to have 7.0 GHz, 8.0 GHz, the resonance peak at each of 9.0GHz and 11.0GHz.

  Then, since the frequencies assigned to the antenna regions 121a to 121e are equally spaced by 1 GHz, the processing unit 54 sets the individual ID for the frequency at which the resonance peak is detected at an interval of 1 GHz to “1”, The individual ID for the frequency at which the resonance peak is not detected is set to “0”, and these binary information “1” and “0” are arranged in, for example, the order of low frequency, and are given to the ID tag 101. ID is recognized. In the ID tag 101 shown in FIG. 4, as described above, resonance peaks are detected at 7.0 GHz, 8.0 GHz, 9.0 GHz, and 11.0 GHz. An ID “11101” in which “1”, “1”, “0”, “1” are arranged in this order is recognized. At this time, the 9.0 GHz resonance peak is due to the reference antenna 120 c having a polarization direction different from that of the other antenna, and can be distinguished from the other resonance peak. Therefore, the antenna 120c is always formed in the antenna region 121c, and the individual IDs are arranged so that the individual ID “1” due to the resonance peak of the antenna 120c is in the center. Even if the antenna 120a or the antenna 120e is not formed in the area 121a or the antenna area 121e to which the highest frequency is assigned, or even if the resonance peak detected by the processing unit 54 is slightly shifted, the ID tag 101 is assigned. Can be accurately recognized.

DESCRIPTION OF SYMBOLS 1,101 ID tag 2 Tag mounting article 3 Article 10, 110 Base substrate 20, 120a to 121c, 121e Antenna 21, 121a to 121e Antenna area 50 Reader 51a Transmission antenna 51b Reception antenna 52 Transmission unit 53 Reception unit 54 Processing unit 55 Control unit

Claims (3)

A base substrate comprising a magnetic material;
An identification body having an antenna that is laminated on one surface of the base substrate and that exhibits a resonance peak by facing a metal through the base substrate. The identification object according to claim 1,
The antenna is an identification body having a Q value of 30 or less when not facing a metal. The identification body according to claim 1 or 2, wherein the identification body is an article mounted with the identification body,
The identifier is attached to the article with the surface of the base substrate opposite to the antenna as an attachment surface,
The article has an identifier-mounted article having a metal that covers the antenna in a plan view in a region where the identifier is attached.

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