JP2016103673A - Identifying body and discrimination system for discriminating id of the identifying body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the number of IDs enabling the identification without increasing an ID size, when IDs can be identified by the combination of a plurality of antennas having resonance frequencies different from each other.SOLUTION: In each of antenna formation regions 20a-20h where antennas having resonance frequencies different from each other are formed, one configuration selected from among a configuration where the antennas are formed on the front and rear of a base substrate 10, a configuration where the antennas are formed on one of the front and the rear of the base substrate 10, and a configuration where the antennas are formed on neither the front nor the rear of the base substrate 10 is selected in accordance with the ID of an ID tag 1.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an identification body that can identify an ID by a combination of a plurality of antennas having different resonance frequencies, and a discrimination system that discriminates the ID of the identification body.

  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 with respect to the label or tag is mounted. 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 frequencies, and the plurality of antennas without using the IC chip. It is also considered that IDs can be identified by a combination. For example, by changing the shape of the dielectric elements and capacitor elements that make up multiple antennas, or by changing the shape and orientation of the multiple antennas to make the resonance frequency different for each of the multiple antennas, Patent Documents 1 and 2 disclose a technique that can express an ID. 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 an identifiable manner.

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

In recent years, as described above, products and the like are managed using IDs in various markets, and accordingly, it is preferable that the number of IDs that can be identifiable is large. As described above, in the case where there are a plurality of antennas having different resonance frequencies and the ID is identifiable by a combination of these antennas, when the number of antennas is N, (2 ^N −1) Therefore, when the number of IDs that can be expressed is increased, the number of antennas is increased, and as a result, the size of the identifier is increased. However, as described above, the identifier is often used by being affixed to a product or the like, and it is not preferable that the size of the identifier is increased.

  The present invention has been made in view of the problems of the conventional technology as described above, and is capable of identifying an ID by a combination of a plurality of antennas having different resonance frequencies. It is an object of the present invention to provide a discriminator that can increase the number of IDs that can be discriminated without discriminating, and a discrimination system that discriminates the IDs of the discriminators.

In order to achieve the above object, the present invention provides:
The base substrate has a plurality of regions in which antennas having different resonance frequencies are formed, and an identification body capable of identifying an ID using the antenna,
Each of the plurality of regions has a configuration in which the antenna is formed on the front and back of the base substrate, a configuration in which the antenna is formed on either the front and back of the base substrate, and a front and back of the base substrate. Any one of the configurations in which the antenna is not formed is selected according to the ID of the identifier.

  In the present invention configured as described above, each of the plurality of regions where the antennas having different resonance frequencies are formed has either a configuration in which the antenna is formed on the front or back of the base substrate, or the front or back of the base substrate. Either the configuration in which the antenna is formed or the configuration in which the antenna is not formed on either of the front and back of the base substrate is a configuration selected according to the ID of the identifier. The peak value of the reflected wave with respect to the radiated electromagnetic wave differs between the configuration in which the antenna is formed on the front and back of the substrate and the configuration in which the antenna is formed on either of the front and back of the base substrate. By detecting the value, it is possible to have two pieces of information using one resonance frequency. In addition, in a configuration in which no antenna is formed on either the front or back of the base substrate, the peak value of the reflected wave with respect to the radiated electromagnetic wave is not detected. Accordingly, for each resonance frequency different from each other, there are three pieces of information: two pieces of information in which the peak value of the reflected wave with respect to the radiated electromagnetic wave is different and one piece of information in which the peak value of the reflected wave with respect to the radiated electromagnetic wave is not detected. The number of IDs that can be identified without increasing the size of each of the resonance frequencies that are different from each other and having two pieces of information “1” and “0” depending on the presence or absence of an antenna. Can be increased.

In addition, the base substrate has a plurality of regions in which antennas having different resonance frequencies are formed, and an identification body capable of identifying an ID depending on whether the antenna is formed for each of the plurality of regions. ,
The antenna is formed by using one material selected from a plurality of materials having different resistance values independently for each of the plurality of regions according to the ID of the identifier.

  In the present invention configured as described above, the antennas having different resonance frequencies are independently selected from a plurality of materials having different resistance values independently for each of a plurality of regions in accordance with the ID of the identifier. However, when an antenna is formed using materials with different resistance values, the peak value of the reflected wave with respect to the radiated electromagnetic wave will be different, and by detecting this peak value, A plurality of pieces of information can be provided using one resonance frequency. Further, in a configuration in which no antenna is formed on the base substrate, the peak value of the reflected wave with respect to the radiated electromagnetic wave is not detected. Thereby, for each resonance frequency different from each other, the peak value of the reflected wave with respect to the radiated electromagnetic wave is different, and a plurality of pieces of information corresponding to the number of materials, and one piece of information where the peak value of the reflected wave with respect to the radiated electromagnetic wave is not detected It is possible to have a plurality of information, and for each resonance frequency different from each other, it is possible to identify without increasing the size compared to the information having two information “1” and “0” depending on the presence or absence of an antenna. The number of possible IDs can be increased.

As an ID discriminating system for discriminating the ID of the identifier mentioned above,
In the identification body, a reference antenna having the lowest or highest resonance frequency is formed in one of the plurality of regions regardless of the ID of the identification body,
Radiation means for radiating electromagnetic waves having a plurality of frequencies including the resonance frequency;
Detecting means for detecting a reflected wave from the antenna with respect to the radiated electromagnetic wave;
Discriminating means for discriminating the ID of the discriminator based on the peak value of the reflected wave detected from the reference antenna and the frequency of the peak value based on the detected peak value of the reflected wave and the frequency of the peak value; A configuration having

  As described above, in the identification body, the reference antenna having the lowest or highest resonance frequency is formed in one of the plurality of regions where the antenna is formed regardless of the ID of the identification body, and reflection from the reference antenna is performed. If the ID of the discriminator is determined based on the peak value of the wave and the frequency of the peak value and based on the detected peak value of the reflected wave and the frequency of the peak value, the resonance frequency and the peak value at that frequency are determined. Even in the case where it differs depending on the environment, the ID of the identifier can be accurately determined.

  According to the present invention, three or more pieces of information can be provided for each resonance frequency by the configuration of the antennas having different resonance frequencies, so that the ID can be identified by a combination of a plurality of antennas having different resonance frequencies. Therefore, the number of IDs that can be identified can be increased without increasing the size.

It is a figure which shows one structural example in 1st Embodiment of the identification body of this invention, (a) is a front view, (b) is a back view, (c) is AA 'shown to (a). Sectional drawing and (d) are BB 'sectional views shown in (a). It is a figure which shows the other structural example in 1st Embodiment of the identification body of this invention, (a) is a front view, (b) is a back view, (c) is AA shown to (a). 'Cross-sectional view, (d) is a cross-sectional view along BB' shown in (a). It is a figure which shows an example of the ID discrimination | determination system which discriminate | determines ID of the ID tag shown in FIG.1 and FIG.2. FIGS. 3A and 3B are diagrams for explaining a method of determining an ID of the ID tag shown in FIGS. 1 and 2, wherein FIG. 3A is a diagram showing basic reflected wave characteristics from the ID tag, and FIG. It is a figure which shows the characteristic of the actual reflected wave from. It is a figure which shows ID discriminate | determined in the ID discrimination | determination part shown in FIG. 3 about the ID tag shown in FIG.1 and FIG.2. It is a figure for demonstrating the setting method of the discrimination | determination reference | standard using a reference | standard antenna, (a) is a figure which shows the setting method of the discrimination | determination reference | standard of a peak value, (b) is a figure which shows the method of correct | amending the deviation | shift of a resonant frequency. It is. It is a figure which shows one structural example in 2nd Embodiment of the identification body of this invention, (a) is a surface figure, (b) is AA 'sectional drawing shown to (a), (c) is It is BB 'sectional drawing shown to (a). It is a figure which shows the other structural example in 2nd Embodiment of the identification body of this invention, (a) is a surface figure, (b) is AA 'sectional drawing shown to (a), (c). FIG. 4 is a cross-sectional view taken along the line BB ′ shown in FIG. It is a figure for demonstrating the method to discriminate | determine ID of the ID tag shown in FIG.7 and FIG.8, (a) is a figure which shows the characteristic of the fundamental reflected wave from an ID tag, (b) is an ID tag It is a figure which shows the characteristic of the actual reflected wave from. It is a figure which shows ID discriminate | determined in the ID discrimination | determination part shown in FIG. 3 about the ID tag shown in FIG.7 and FIG.8.

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

(First embodiment)
FIG. 1 is a diagram showing an example of the configuration of the identifier according to the first embodiment of the present invention, where (a) is a front view, (b) is a back view, and (c) is shown in (a). AA 'sectional drawing, (d) is BB' sectional drawing shown to (a). Note that the back view of FIG. 1B shows the configuration of the back surface viewed from the front surface side so that the positional relationship with the front view of FIG.

  As shown in FIG. 1, the identification body of this example is an ID tag 1 having eight antenna formation regions 20 a to 20 h on a base substrate 10. In the ID tag 1, antennas 31 a to 31 d and 31 f to 31 h are respectively formed in the antenna formation regions 20 a to 20 d and 20 f to 20 h among the antenna formation regions 20 a to 20 h on the surface of the base substrate 10. On the back surface of the base substrate 10, antennas 32b, 32d, 32f, and 32g are formed in the antenna formation regions 20b, 20d, 20f, and 20g, respectively, of the antenna formation regions 20a to 20h.

  The antennas formed in the antenna formation regions 20a to 20h have the same shape on each of the front and back surfaces of the base substrate 10 for each of the antenna formation regions 20a to 20h, and thereby have the same resonance frequency. In addition, the antennas formed in the antenna formation regions 20a to 20h have different shapes from each other in the antenna formation regions 20a to 20h, and thus have different resonance frequencies.

  Specifically, the antenna 31a formed in the antenna formation region 20a is a square, whereas the antennas 31b, 32b, 31c, 31d, and 32d formed in the antenna formation regions 20b to 20d, respectively, Two stubs are provided in a square whose side is shorter than the antenna 31a. In addition, the antennas 31f, 32f, 31g, 32g, and 31h formed in the antenna formation regions 20f to 20h have two stubs in a square whose side is shorter than the antennas 31b, 32b, 31c, 31d, and 32d, respectively. Is provided. The antennas 31b and 32b, the antenna 31c, the antennas 31d and 32d, the antennas 31f and 32f, the antennas 31g and 32g, and the antenna 31h have different stub lengths and positions. Is different. Note that the resonance frequency can also be varied by varying the line width of the stub.

  In general, the resonance frequency of the antenna decreases as the size thereof increases, and the resonance frequency decreases as the length of the stub increases. In the ID tag 1 of this example, the resonance frequency of the antenna 31a formed in the antenna formation region 20a is the lowest, and then formed in the antennas 31b and 32b formed in the antenna formation region 20b, and then in the antenna formation region 20c. Antenna 31c, then antennas 31d and 32d formed in antenna formation region 20d, then antennas 31f and 32f formed in antenna formation region 20f, then antennas 31g and 32g formed in antenna formation region 20g, The resonance frequency increases in the order of the antenna 31h formed in the antenna formation region 20h. The antenna 31a having the lowest resonance frequency is set as the reference antenna.

  FIGS. 2A and 2B are diagrams showing another configuration example of the identifier according to the first embodiment of the present invention. FIG. 2A is a front view, FIG. 2B is a back view, and FIG. AA 'sectional view, (d) is a BB' sectional view shown in (a). 2B also shows the configuration of the back surface viewed from the front surface side so that the positional relationship with the front surface view of FIG. 2A is clear, as in FIG.

  As shown in FIG. 2, the identifier of this example is an ID tag 101 having eight antenna forming regions 120 a to 120 h in the base substrate 110, as in the ID tag 1 shown in FIG. 1. In the ID tag 101, antennas 131a to 131d and 131f to 131h are formed in the antenna formation regions 120a to 120d and 120f to 120h among the antenna formation regions 120a to 120h on the surface of the base substrate 110. On the back surface of the base 110, antennas 132c and 132h are formed in the antenna formation regions 120c and 120h among the antenna formation regions 120a to 120h.

  Here, in the ID tag 101 in this example, the antennas formed in the antenna formation regions 120a to 120h have the same shape as the antennas formed in the antenna formation regions 20a to 20h in the ID tag 1 shown in FIG. Thereby, the resonance frequency is the same. Specifically, the antenna 131a formed in the antenna formation region 120a has the same shape as the antenna 31a formed in the antenna formation region 20a in the ID tag 1 shown in FIG. The antenna 131b formed in the antenna formation region 120b has the same shape as the antennas 31b and 32b formed in the antenna formation region 20b in the ID tag 1 shown in FIG. The antennas 131c and 132c formed in the antenna formation region 120c have the same shape as the antenna 31c formed in the antenna formation region 20c in the ID tag 1 shown in FIG. The antenna 131d formed in the antenna formation region 120d is the ID shown in FIG. 1 has the same shape as the antennas 31d and 32d formed in the antenna formation region 20d and the resonance frequency is the same, and the antenna 131f formed in the antenna formation region 120f is shown in FIG. The antenna 131g formed in the antenna formation region 120g has the same shape as the antennas 31f and 32f formed in the antenna formation region 20f of the ID tag 1 and has the same resonance frequency. The ID tag 1 has the same shape as the antennas 31g and 32g formed in the antenna formation region 20g and the same resonance frequency, and the antennas 131h and 132h formed in the antenna formation region 120h Same as the antenna 31h formed in the antenna formation region 20h in the ID tag 1 shown in FIG. Resonant frequency has a Jo has become identical. That is, the ID tag 101 in this example has the same surface configuration as that of the ID tag 1 shown in FIG. Thereby, in the ID tag 101 in this example, the antenna 131a having the lowest resonance frequency is set as the reference antenna.

  Hereinafter, an ID determination method using the ID tags 1 and 101 configured as described above will be described.

  FIG. 3 is a diagram showing an example of an ID discrimination system that discriminates the IDs of the ID tags 1 and 101 shown in FIGS. 1 and 2.

  As shown in FIG. 3, the ID discrimination system in this example includes an antenna 41, an electromagnetic wave emission unit 42 as a radiation unit, a reflected wave detection unit 43 as a detection unit, and an ID discrimination unit 44 as a discrimination unit. doing.

  The electromagnetic wave radiation unit 42 radiates electromagnetic waves in the frequency band via the antenna 41 while sweeping a frequency band including the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h. In the electromagnetic wave radiation part 42, the frequency bands including the resonance frequencies of the antennas formed in the antenna formation regions 20a to 20h and 120a to 120h are not swept, but formed in the antenna formation regions 20a to 20h and 120a to 120h. The antenna may be configured to radiate electromagnetic waves having a resonance frequency at the same time. That is, the electromagnetic wave radiation part 42 radiates electromagnetic waves having a plurality of frequencies including the resonance frequencies of the antennas formed in the antenna formation regions 20 a to 20 h and 120 a to 120 h via the antenna 41.

  The reflected wave detection unit 43 detects a reflected wave with respect to the electromagnetic wave radiated from the electromagnetic wave radiation unit 42 via the antenna 41. When electromagnetic waves are radiated from the electromagnetic wave radiation section 42 to the ID tags 1 and 101 shown in FIGS. 1 and 2 via the antenna 41, the antennas 31a to 31d, 31f to 31h, 32b, Reflected waves from 32d, 32f, 32g, 131a to 131d, 131f to 131h, 132c, and 132h are detected via the antenna 41.

  The ID discriminating unit 44 detects the reflected wave detected by the reflected wave detecting unit 43 based on the peak value of the reflected wave from the reference antennas 20a and 120a and the frequency of the peak value. Based on the peak value of the reflected wave from the other antenna and the frequency of the peak value, the IDs of the ID tags 1 and 101 are determined.

  In the ID tags 1 and 101 shown in FIGS. 1 and 2, as described above, the resonance frequency is different for each antenna formed in the antenna formation regions 20a to 20h and 120a to 120h. Therefore, the electromagnetic wave radiation part 42 radiates the electromagnetic wave in the frequency band through the antenna 41 while sweeping the frequency band including the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h, and the reflection thereof. If the wave is detected by the reflected wave detection unit 43, the antenna forming region 20a to 20h, 120a to 120h is reflected at the resonance frequency of the antenna formed in the antenna forming region in the region where the antenna is formed. In a region where a wave peak value exists and no antenna is formed, there is no peak value of a reflected wave at the resonance frequency of the antenna formed in the antenna formation region.

  Therefore, in the ID tag 1 shown in FIG. 1 and the ID tag 101 shown in FIG. 2, the configurations of the antenna formation regions 20a to 20h and 120a to 120h are the same only by the configuration of the surfaces of the base substrates 10 and 110. Therefore, the electromagnetic wave radiation part 42 radiates the electromagnetic wave in the frequency band through the antenna 41 while sweeping the frequency band including the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h. When the reflected wave is detected by the reflected wave detection unit 43, a peak value exists at the same resonance frequency and cannot be distinguished from each other.

  Here, the ID tag 1 shown in FIG. 1 and the ID tag 101 shown in FIG. In the ID tag 1 shown in FIG. 1, the antennas 31b and 32b are formed on the front and back of the base substrate 10 in the antenna formation region 20b, whereas in the ID tag 101 shown in FIG. The antenna 131b is formed only on the surface of the base substrate 110. In the ID tag 1 shown in FIG. 1, the antenna 31c is formed only on the surface of the base substrate 10 in the antenna formation region 20c, whereas in the ID tag 101 shown in FIG. 2, the antenna formation region 120c is formed. The antennas 131c and 132c are formed on the front and back of the base substrate 110. Further, in the ID tag 1 shown in FIG. 1, the antennas 31d and 32d are formed on the front and back of the base substrate 10 in the antenna formation region 20d, whereas in the ID tag 101 shown in FIG. In 120c, the antenna 131d is formed only on the surface of the base substrate 110. Further, in the ID tag 1 shown in FIG. 1, the antennas 31g and 32g are formed on the front and back of the base substrate 10 in the antenna formation region 20g, while the antenna formation region is formed in the ID tag 101 shown in FIG. At 120 g, the antenna 131 g is formed only on the surface of the base substrate 110.

  As described above, when the antenna is formed on the front and back surfaces of the base materials 10 and 110 and when the antenna is formed only on the surface of the base materials 10 and 110, the peak of the reflected wave at the resonance frequency of the antenna. The value will be different. This is not limited to the case where the antenna is formed only on the surfaces of the base substrates 10 and 110, and the same applies to the case where the antenna is formed on either the front or back of the base substrates 10 and 110.

  FIG. 4 is a diagram for explaining a method of discriminating the IDs of the ID tags 1 and 101 shown in FIGS. 1 and 2, and (a) is a characteristic of a fundamental reflected wave from the ID tags 1 and 101. FIG. 5B is a diagram showing the characteristics of the actual reflected wave from the ID tags 1 and 101. FIG.

  As described above, in the case where the antenna is formed on the front and back surfaces of the base base materials 10 and 110 and the case where the antenna is formed on either the front and back surfaces of the base base materials 10 and 110, the resonance frequency of the antenna is determined. The peak value of the reflected wave is different. Specifically, as shown in FIG. 4A, the reflected wave when the antenna is formed on the front and back of the base substrates 10 and 110 is as shown by a solid line. The reflected wave when the antenna is formed on either of the front and back sides is as shown by the broken line, and the peak value of the reflected wave when the antenna is formed on the front and back of the base base materials 10 and 110 is the base The loss is smaller than the peak value of the reflected wave when the antenna is formed on either the front or back of the base material 10 or 110. This is because the antennas formed on the front and back surfaces of the base substrates 10 and 110 perform a booster function and strengthen the reflected waves.

  Therefore, the peak value of the reflected wave when the antenna is formed on the front and back surfaces of the base base materials 10 and 110 and the peak value of the reflected wave when the antenna is formed on either the front and back surfaces of the base base materials 10 and 110. Whether the antenna is formed on the front and back surfaces of the base materials 10 and 110 in the antenna formation region where the antenna having the resonance frequency where the peak value exists is formed by providing the discrimination line A to the loss value between the values. It is possible to distinguish whether the antenna is formed on either the front or back of the base substrate 10 or 110. That is, two cases using one resonance frequency in the case where the antenna is formed on the front and back sides of the base base materials 10 and 110 and the case where the antenna is formed on either the front and back sides of the base base materials 10 and 110. You can have information. Further, in the antenna formation region where the antenna is not formed, there is no peak value at the resonance frequency of the antenna, so that the reflected wave in the case where the antenna is formed on either the front or back of the base substrates 10 and 110 By providing the discrimination line B at a loss value larger than the peak value, it can be discriminated that the antenna is not formed in the antenna formation region where the antenna having the resonance frequency is formed. Thus, for each resonance frequency different from each other, it is possible to have three pieces of information, that is, two pieces of information with different peak values of the reflected wave with respect to the radiated electromagnetic wave and one piece of information with which the reflected wave with respect to the radiated electromagnetic wave is not detected. it can.

In the ID tags 1 and 101 shown in FIGS. 1 and 2, the resonance frequency of the antenna formed in the antenna formation regions 20a and 120a is f ₀ , and the resonance frequency of the antenna formed in the antenna formation regions 20b and 120b is f ₁ , the resonance frequency of the antenna formed in the antenna formation regions 20c, 120c is f ₂ , the resonance frequency of the antenna formed in the antenna formation regions 20d, 120d is f ₃ , and the antenna formation regions 20e, 20e, The resonance frequency of the antenna formed in 120e is f ₄ , the resonance frequency of the antenna formed in the antenna formation regions 20f and 120f is f ₅ , and the resonance frequency of the antenna formed in the antenna formation regions 20g and 120g is f ₆ and the resonance frequency of the antenna formed in the antenna formation regions 20h and 120h is f ₇ To do. Then, when the electromagnetic wave radiation part 42 radiates the electromagnetic wave in the frequency band through the antenna 41 while sweeping the frequency band including the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h, the ID In the tag 1, as shown by the solid line in FIG. 4B, the peak value of the reflected wave at the resonance frequency f ₀ of the antenna formed in the antenna formation region 20a exists between the discrimination lines A and B. The peak value of the reflected wave at the resonance frequency f ₁ of the antenna formed in the antenna formation region 20b is smaller than the discrimination line A, and the peak value of the reflection wave at the resonance frequency f ₂ of the antenna formed in the antenna formation region 20c. exists between the discrimination line a and B, the resonance frequency f ₃ of the antenna formed on the antenna forming region 20d Kicking peak value of the reflected wave becomes smaller than the determination line A, the peak value of the reflected wave at the resonance frequency f ₄ of the antenna formed on the antenna forming region 20e is larger than the loss in the absence of a determination line B Thus, the peak value of the reflected wave at the resonance frequency f ₅ of the antenna formed in the antenna formation region 20f is smaller than the discrimination line A, and the reflected wave at the resonance frequency f ₆ of the antenna formed in the antenna formation region 20g The peak value is smaller than that of the discrimination line A, and the peak value of the reflected wave at the resonance frequency f ₇ of the antenna formed in the antenna formation region 20 h exists between the discrimination lines A and B. On the other hand, in the ID tag 101, as shown by a broken line in FIG. 4B, the peak value of the resonance frequency f ₀ of the antenna formed in the antenna formation region 120a exists between the discrimination lines A and B. The peak value of the resonance frequency f ₁ of the antenna formed in the antenna formation region 120b exists between the discrimination lines A and B, and the peak value of the resonance frequency f ₂ of the antenna formed in the antenna formation region 120c is the discrimination line. A peak value of the resonance frequency f ₃ of the antenna formed in the antenna formation region 120d exists between the discrimination lines A and B, and the resonance frequency f of the antenna formed in the antenna formation region 120e is smaller than A. peak ₄ becomes larger than the loss in the absence of a discrimination line B, peak of the resonance frequency f ₅ of the antenna formed on the antenna forming region 120f Click value is present between the determination line A and B, the peak value of the resonance frequency f ₆ of the antenna formed on the antenna forming region 120g is present between the determination line A and B, the antenna formation region 120h The peak value of the resonance frequency f ₇ of the formed antenna is smaller than the discrimination line A.

Thus, each of the antenna formation regions 20a to 20h and 120a to 120h has a configuration in which an antenna is formed on the front and back sides of the base base materials 10 and 110, and an antenna is formed on either the front and back sides of the base base materials 10 and 110. Since the antenna is not formed on either of the front and back surfaces of the base substrates 10 and 110, the antenna forming regions 20a to 20h and 120a to 120h have resonance frequencies with each other. Three pieces of information can be provided for each resonance frequency of antennas formed differently, and an ID can be configured using these three pieces of information. When the number of antenna forming areas is N, one piece of information is fixed for the antenna forming area where the reference antenna is formed, so 3 ^N-1 IDs can be configured. .

  FIG. 5 is a diagram showing IDs discriminated by the ID discrimination unit 44 shown in FIG. 3 for the ID tags 1 and 101 shown in FIG. 1 and FIG.

  Using the characteristics described above, in the ID determination unit 44, the peak value of the reflected wave at the resonance frequency is determined from the determination line A for each resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h. The ID of the ID tag 1, 101 is determined by setting “2” for the smaller one, “1” for the one existing between the discrimination lines A and B, and “0” for the one larger than the discrimination line B.

  As shown in FIG. 5, the ID tag 1 is “12120221”, the ID tag 101 is “11210112”, and the surfaces of the base base materials 10 and 110 are arranged in the order from the lowest resonance frequency. The ID tag 1 and the ID tag 101 having the same configuration can be distinguished from each other. Note that the reflected wave having the lowest resonance frequency is a reflected wave from the reference antennas 20a and 120a, and thus is not used as an ID. The ID of the ID tag 1 is “21220221”, and the ID of the ID tag 101 is “ 1210112 ".

  As described above, the ID tags 1 and 101 shown in FIGS. 1 and 2 have a configuration in which an antenna is formed on the front and back sides of the base base materials 10 and 110, and an antenna on either the front or back side of the base base materials 10 and 110. Either the formed configuration or the configuration in which the antenna is not formed on either of the front and back surfaces of the base substrates 10 and 110 is selected according to the ID of the ID tag 1 or 101. As a result, three pieces of information can be given for each resonance frequency, and IDs can be identified by a combination of a plurality of antennas having different resonance frequencies, and can be identified without increasing the size. The number of IDs can be increased.

  The reason why the reference antennas 31a and 131a are provided in the ID tags 1 and 101 shown in FIGS. 1 and 2 will be described below.

  FIGS. 6A and 6B are diagrams for explaining a discrimination criterion setting method using the reference antennas 31a and 131a. FIG. 6A is a diagram illustrating a peak value discrimination criterion setting method, and FIG. 6B is a resonance frequency shift. It is a figure which shows the method of correct | amending.

  The ID tags 1 and 101 shown in FIGS. 1 and 2 have different peak values depending on the distance between the ID tag 1 and 101 and the antenna 41 when the reflected wave detection unit 43 shown in FIG. It will be. Therefore, even if the discrimination line as described above is set, the antenna is formed on either the front or back side of the base base material 10 or 110 and the configuration where the antenna is formed on the front or back side of the base base material 10 or 110. There is a possibility that the configuration and the configuration in which the antenna is not formed on either of the front and back surfaces of the base base materials 10 and 110 cannot be distinguished.

  Therefore, the discrimination line is set based on the peak value of the reflected wave at the resonance frequency of the reference antennas 31a and 131a.

For example, when the frequency characteristics of the reflected waves from the reference antennas 31a and 131a are as shown by the solid line in FIG. 6A, a configuration in which antennas are formed on the front and back of the base substrates 10 and 110, and the base substrate A discriminating line A ₁ for distinguishing the configuration in which the antenna is formed on either of the front and back surfaces of 10, 110, and a configuration in which the antenna is formed on either of the front and back surfaces of the base substrates 10, 110; A discrimination line B ₁ is set for distinguishing the configuration in which the antenna is not formed on either of the front and back surfaces of the base substrates 10 and 110. Further, in the case where the frequency characteristics of the reflected waves from the reference antennas 31a and 131a are as shown by the broken lines in FIG. 6A, a configuration in which antennas are formed on the front and back of the base substrates 10 and 110, and the base substrate A discriminant line A ₂ for distinguishing the configuration in which the antenna is formed on either of the front and back surfaces of 10, 110, and a configuration in which the antenna is formed on either of the front and back surfaces of the base substrates 10, 110; A discrimination line B ₂ is set for distinguishing the configuration in which the antenna is not formed on either of the front and back surfaces of the base substrates 10 and 110.

  Thereby, for the ID tags 1 and 101 shown in FIGS. 1 and 2, the peak value of the reflected wave detected by the reflection detection unit 43 shown in FIG. 3 depends on the distance between the ID tag 1 and 101 and the antenna 41. Even in different cases, a configuration in which antennas are formed on the front and back sides of the base substrates 10 and 110, a configuration in which antennas are formed on either the front and back sides of the base substrates 10 and 110, and It becomes possible to distinguish from a configuration in which no antenna is formed on either of the front and back sides.

  Further, in the ID tags 1 and 101 shown in FIG. 1 and FIG. 2, when affixed to a product or the like, the resonance frequency of each antenna is shifted. Therefore, it becomes impossible to accurately detect the peak value of the reflected wave at the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h.

  Therefore, the antennas 20a and 120a having the lowest resonance frequency are used as reference antennas, and the resonance frequencies of the antennas formed in the antenna formation regions 20a to 20h and 120a to 120h are shifted based on the shift amounts of the reference antennas. The peak value of the reflected wave at the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h can be accurately detected.

For example, as shown by the solid line in FIG. 6B, when the resonance frequency f ₀ of the reference antennas 20a and 120a is shifted to f ₁ on the low frequency side, antennas formed in the antenna formation regions 20a to 20h and 120a to 120h. Are respectively shifted to the lower frequency side by a frequency obtained by multiplying (f ₀ −f ₁ ) by a predetermined coefficient. 6B, when the resonance frequency f ₀ of the reference antennas 20a and 120a is shifted to f ₂ on the low frequency side, the antenna formation regions 20a to 20h and 120a to 120h are formed. The resonance frequency of the antenna is shifted to the lower frequency side by a frequency obtained by multiplying (f ₀ −f ₂ ) by a predetermined coefficient. Note that the predetermined coefficient is calculated in advance based on a previous measurement value.

  Thereby, even if it is a case where the resonance frequency of each antenna shifts when ID tag 1,101 is stuck to goods etc., in the resonance frequency of the antenna formed in antenna formation area 20a-20h, 120a-120h. It becomes possible to accurately detect the peak value of the reflected wave.

  Note that the antennas 20a and 120a having the lowest resonance frequency are used as reference antennas, as described above, when the ID tag 1 or 101 is attached to a product or the like, the resonance frequency of each antenna shifts. Therefore, if the antennas 20a and 120a having the lowest resonance frequency are used as reference antennas, the antenna having the lowest resonance frequency of the detected reflected wave is recognized as the reference antenna, and the frequency characteristics are shifted. This is because you will be able to.

  In addition, when the ID tag 1 or 101 is attached to a product or the like, the resonance frequency of each antenna is generally shifted to a low frequency. However, if a metal exists in the vicinity of the ID tag 1 or 101, resonance occurs due to multiple resonance. The frequency may shift to a higher frequency. Therefore, in the case of broadband in which the resonance frequency of the antenna formed in the antenna formation regions 20a to 20h and 120a to 120h is equal to or higher than twice the lowest resonance frequency, the peak of the reflected wave and the double resonance peak Therefore, it is necessary to use the antennas 20a and 120a having the lowest resonance frequency as reference antennas. However, the resonance frequencies of the antennas formed in the antenna formation regions 20a to 20h and 120a to 120h have multiple resonances. In the case of a narrow band having a narrow frequency band that does not occur, the antenna having the highest resonance frequency can be set as the reference antenna, not limited to the antenna having the lowest resonance frequency. Thus, in one of the plurality of regions in which the antenna is formed, a reference having the lowest or highest resonance frequency regardless of the ID of the identification object, depending on the resonance frequency width of the antenna formed in the plurality of regions. By forming the antenna, it is possible to accurately determine the ID of the identification object using the reflected wave from another antenna on the basis of the peak value of the reflected wave from the reference antenna and the frequency of the peak value. .

(Second Embodiment)
FIG. 7 is a diagram showing an example of the configuration of the discriminator according to the second embodiment of the present invention, in which (a) is a front view, (b) is a cross-sectional view along AA ′ shown in (a), (C) is BB 'sectional drawing shown to (a).

  As shown in FIG. 7, the identification body of this example is an ID tag 201 having eight antenna forming regions 220a to 220h in the base substrate 210, similar to those shown in FIGS. Antennas 230a to 230h are formed on the surface of the base substrate 210 in each of the eight antenna formation regions 220a to 220h.

  The antennas 230a to 230h formed in the antenna formation regions 220a to 220h are formed using silver as a material, and the shapes thereof are different from each other in the antenna formation regions 220a to 220h, and thus have different resonance frequencies.

  Specifically, the antennas 230a to 230h formed in the antenna formation regions 220a to 220h have a coil shape and the same outer shape, but the number of turns is the antenna formed in the antenna formation region 220a. 230a is the largest, then the antenna 230b formed in the antenna formation region 220b, then the antenna 230c formed in the antenna formation region 220c, then the antenna 230d formed in the antenna formation region 220d, and then the antenna formation region 220e. The antenna 230e is formed in the antenna formation region 220f, then the antenna 230f is formed in the antenna formation region 220f, and then the antenna 230g is formed in the antenna formation region 220g. Number of turns of the antenna 230h has become the least. Accordingly, the resonance frequencies are different from each other. In the ID tag 201 of this example, the resonance frequency of the antenna 230a formed in the antenna formation region 220a is the lowest, and then the antenna 230b formed in the antenna formation region 220b, Next, the antenna 230c formed in the antenna formation region 220c, then the antenna 230d formed in the antenna formation region 220d, then the antenna 230e formed in the antenna formation region 220e, and then the antenna formed in the antenna formation region 220f The resonance frequency is higher in the order of 230f, then the antenna 230g formed in the antenna formation region 220g, and then the antenna 230h formed in the antenna formation region 220h. The antenna 230a having the lowest resonance frequency is set as the reference antenna.

  FIGS. 8A and 8B are diagrams showing another configuration example of the discriminator according to the second embodiment of the present invention. FIG. 8A is a front view, and FIG. (C) is BB 'sectional drawing shown to (a).

  As shown in FIG. 8, the structure of the identifier of this example is the same as that shown in FIG. 7, except that the antennas 330a to 330h formed in the antenna formation regions 320a to 320h are made of carbon. The ID tag 301 is different from that shown in FIG.

  As described above, in this embodiment, the ID tag 201 shown in FIG. 7 and the ID tag 301 shown in FIG. 8 have the antennas 230a to 230h and 330a to 330a formed in the antenna formation regions 220a to 220h and 320a to 320h. 330h is formed of materials having different resistance values. When the antennas 230a to 230h and 330a to 330h formed in the antenna formation regions 220a to 220h and 320a to 320h are formed of materials having different resistance values, the peak values of the reflected waves at the resonance frequency are different from each other. Become.

  FIG. 9 is a diagram for explaining a method of discriminating the IDs of the ID tags 201 and 301 shown in FIGS. 7 and 8, and (a) is a characteristic of a basic reflected wave from the ID tags 201 and 301. (B) is a figure which shows the characteristic of the actual reflected wave from ID tag 201,301.

  As described above, when the antennas 230a to 230h and 330a to 330h formed in the antenna formation regions 220a to 220h and 320a to 320h are formed of materials having different resistance values, the peak value of the reflected wave at the resonance frequency Will be different. Specifically, as shown in FIG. 9A, the reflected waves of the antennas 230a to 230h formed using silver as a material in the antenna formation regions 220a to 220h are as indicated by solid lines, and the antenna formation region 320a. The reflected waves of the antennas 330a to 330h formed of carbon at ˜320h are as indicated by broken lines, and the peak values of the reflected waves of the antennas 230a to 230h formed of silver at the antenna formation regions 220a to 220h However, the loss is smaller than the peak value of the reflected wave of the antennas 330a to 330h formed using carbon as a material in the antenna formation regions 320a to 320h. This is because the resistance value of silver is smaller than the resistance value of carbon.

  Therefore, the peak values of the reflected waves of the antennas 230a to 230h formed using silver as the material in the antenna forming regions 220a to 220h and the reflected waves of the antennas 330a to 330h formed using carbon as the material in the antenna forming regions 320a to 320h are described. By providing a discriminant line A to the loss value between the peak value and the antenna forming region where the antenna having the resonance frequency where the peak value exists is formed, whether the antenna is formed of silver or carbon. It can be distinguished whether an antenna is formed as a material. That is, by selectively forming an antenna using silver and carbon as materials, it is possible to have two pieces of information using one resonance frequency. Further, in the antenna formation region where the antenna is not formed, there is no peak value at the resonance frequency of the antenna, so the peak of the reflected wave of the antennas 330a to 330h formed of carbon in the antenna formation regions 320a to 320h. By providing the discrimination line B at a loss value larger than the value, it can also be discriminated that no antenna is formed in the antenna formation region where the antenna having the resonance frequency is formed. Thus, for each resonance frequency different from each other, it is possible to have three pieces of information, that is, two pieces of information with different peak values of the reflected wave with respect to the radiated electromagnetic wave and one piece of information with which the reflected wave with respect to the radiated electromagnetic wave is not detected. it can. As a method of changing the resistance value without changing the resonance frequency, there is also a method of changing the line width, line spacing, and thickness of the coiled antenna.

In the ID tags 201 and 301 shown in FIGS. 7 and 8, the resonance frequency of the antenna formed in the antenna formation regions 220a and 320a is f ₀ , and the resonance frequency of the antenna formed in the antenna formation regions 220b and 320b is f ₁ , the resonance frequency of the antenna formed in the antenna formation regions 220c and 320c is f ₂ , the resonance frequency of the antenna formed in the antenna formation regions 220d and 320d is f ₃ , and the antenna formation regions 220e, The resonance frequency of the antenna formed in 320e is f ₄ , the resonance frequency of the antenna formed in the antenna formation regions 220f and 320f is f ₅ , and the resonance frequency of the antenna formed in the antenna formation regions 220g and 320g is It is f _6, an antenna formation region 220h, co of the antenna formed on 320h Frequency is assumed to be f _7. Then, in the electromagnetic wave radiation part 42 shown in FIG. 3, the electromagnetic wave in the frequency band is passed through the antenna 41 while sweeping the frequency band including the resonance frequency of the antenna formed in the antenna formation regions 220 a to 220 h and 320 a to 320 h. When radiated, in the ID tag 201, as indicated by the solid line in FIG. 9B, the peak values of the reflected waves at the resonance frequencies f _{0 to} f ₇ of the antennas formed in the antenna formation regions 220a to 220h are , And smaller than the discrimination line A. On the other hand, in the ID tag 301, as indicated by the broken lines in FIG. 9B, the peak values of the reflected waves at the resonance frequencies f _{0 to} f ₇ of the antennas formed in the antenna formation regions 320a to 320h are determined. It exists between lines A and B.

  As described above, the antenna materials formed in the antenna formation regions 220a to 220h and 320a to 320h have different resistance values, so that the antenna formation regions 220a to 220h and 320a to 320h have resonance frequencies with each other. Can be given for each resonance frequency of the antennas formed to be different from each other, and further, three pieces of information including the case where the antennas are not formed in the antenna formation regions 220a to 220h and 320a to 320h. The ID can be configured using.

  FIG. 10 is a diagram showing IDs discriminated by the ID discriminating unit 44 shown in FIG. 3 for the ID tags 201 and 301 shown in FIG. 7 and FIG.

  Using the characteristics described above, in the ID determination unit 44, the peak value of the reflected wave at the resonance frequency is determined from the determination line A for each resonance frequency of the antenna formed in the antenna formation regions 220a to 220h and 320a to 320h. The ID tags 201 and 301 are discriminated by setting “2” to be smaller, “1” to be present between the discrimination lines A and B, and “0” being greater than the discrimination line B.

  As shown in FIG. 10, when the arrangement order is from the lowest resonance frequency, the ID tag 201 becomes “222222222”, the ID tag 301 becomes “11111111”, and the surfaces of the base substrates 210 and 310 The ID tag 201 and the ID tag 301 having the same configuration can be distinguished from each other. Note that the reflected wave having the lowest resonance frequency is a reflected wave from the reference antennas 220a and 320a, and thus is not used as an ID. The ID of the ID tag 201 is “2222222”, and the ID of the ID tag 301 is “ 1111111 ".

  In this embodiment, for the ID tag 201, the antennas 230a to 230h are formed in all of the antenna formation regions 220a to 220h, and all of these antennas 230a to 230h are formed using silver. In the ID tag 301, antennas 330a to 330h are formed in all of the antenna formation regions 320a to 320h, and all of these antennas 330a to 330h are formed using carbon, but the antenna formation regions 220a to 220h. , 320a to 320h, an ID as shown in the first embodiment can be configured by selecting a material for forming the antenna and providing a region where the antenna is not formed. In other words, in this embodiment, the antennas 230a to 230h and 330a to 330h are independently selected for each of the antenna formation regions 220a to 220h and 320a to 320h according to the ID of the ID tags 201 and 301. And formed using a selected material. For example, in the ID tag 201, the antenna 230b is formed using silver in the antenna formation region 220b, the antenna 230c is formed using carbon in the antenna formation region 220c, and no antenna is formed in the antenna formation region 220d. As described above, in one ID tag, an antenna formed using silver and an antenna formed using carbon are mixed, and among them, as shown in FIGS. Depending on the ID, in one ID tag, all antennas may be made of silver or carbon.

  In addition, the material forming the antenna is not limited to silver or carbon, and any material having different resistance values may be used. If the number is increased from two, more information about one resonance frequency can be given. Can do. Further, even more information can be provided by making the antenna shapes different from each other.

  Further, in this embodiment, the resonance frequency of the antennas 230a to 230h is made different by making the number of turns of the antennas 230a to 230h formed in the antenna formation regions 220a to 220h different from each other. The resonance frequency may be varied by varying the line width, line spacing, and thickness of .about.230h.

  As described above, in this embodiment, the antennas 230a to 230h and 330a to 330h formed in the antenna formation regions 220a to 220h and 320a to 320h are replaced with one material from a plurality of materials having different resistance values. By selecting the ID tags 201 and 301 according to the IDs of the ID tags 201 and 301 for each of ~ 220h and 320a to 320h and using the material, three or more pieces of information can be provided for each resonance frequency. In the case where IDs can be identified by a combination of a plurality of antennas having different frequencies, the number of IDs that can be identified can be increased without increasing the size.

  In the above-described embodiment, the antenna has been described as an example of a square, a square-shaped stub or a coil, but the antenna is circular, rectangular, slit-shaped, etc. Can be appropriately selected.

1, 101, 201, 301 ID tag 10, 110, 210, 310 Base substrate 20a-20h, 120a-120h, 220a-220h, 320a-320h Antenna formation region 31a-31d, 31f-31h, 32b, 32d, 32f , 32g, 41, 131a to 131d, 131f to 131h, 132c, 132h, 230a to 230h, 330a to 330h Antenna 42 Electromagnetic wave radiation unit 43 Reflected wave detection unit 44 ID discrimination unit

Claims (3)

The base substrate has a plurality of regions in which antennas having different resonance frequencies are formed, and an identification body capable of identifying an ID using the antenna,
Each of the plurality of regions has a configuration in which the antenna is formed on the front and back of the base substrate, a configuration in which the antenna is formed on either the front and back of the base substrate, and a front and back of the base substrate. Any one of the configurations in which the antenna is not formed in any of them is selected according to the ID of the identifier. The base substrate has a plurality of regions where antennas having different resonance frequencies are formed, and an identification body that can identify an ID depending on whether the antenna is formed for each of the plurality of regions,
The antenna is an identification body formed by using one material selected from a plurality of materials having different resistance values independently for each of the plurality of regions according to the ID of the identification body. An ID discrimination system for discriminating an ID of an identifier according to claim 1 or claim 2,
In the identification body, a reference antenna having the lowest or highest resonance frequency is formed in one of the plurality of regions regardless of the ID of the identification body,
Radiation means for radiating electromagnetic waves having a plurality of frequencies including the resonance frequency;
Detecting means for detecting a reflected wave from the antenna with respect to the radiated electromagnetic wave;
Discriminating means for discriminating the ID of the discriminator based on the peak value of the reflected wave detected from the reference antenna and the frequency of the peak value based on the detected peak value of the reflected wave and the frequency of the peak value; ID discriminating system.

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