JP2018152664A - Communication sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize stable communication while maintaining the degree of freedom for width of a communication sheet.SOLUTION: A communication sheet 100 includes: a first conductor layer 110 with mesh-like openings formed; a second conductor layer; an insulator layer provided between the first conductor layer 110 and the second conductor layer; and an electromagnetic wave interface 200 for generating an electromagnetic wave corresponding to a received electric signal. A shape of the communication sheet 100 viewed from a thickness direction is a rectangle including two long sides extending toward a longitudinal direction orthogonal to the thickness direction and two short sides extending toward a width direction orthogonal to the thickness direction and longitudinal direction. The electromagnetic wave interface 200 is provided on part of one short side of the two short sides. The first conductor layer 110 includes slits 111A and 111B extending from the one short side toward the longitudinal direction.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a communication sheet.

  Currently, two-dimensional communication using a communication sheet is known. The communication sheet is configured, for example, by sequentially laminating a first conductor layer in which mesh-shaped openings are formed, an insulator layer, and a second conductor layer. The electromagnetic wave propagating through the inside of the communication sheet is leached from the mesh-shaped opening and generates a near field on the surface of the communication sheet. Here, if there is unevenness in the strength of the electromagnetic wave leached from the surface of the communication sheet, stable two-dimensional communication cannot be realized. For example, when a communication device is arranged on a portion where the intensity of electromagnetic waves is extremely weak (hereinafter referred to as “null point”) on the communication sheet, the communication device cannot receive electromagnetic waves from the communication sheet. For this reason, in order to implement | achieve stable two-dimensional communication, it is desired not to generate a null point on a communication sheet.

  Here, when the electromagnetic wave is reflected at the end of the communication sheet, a standing wave is generated on the communication sheet, and as a result, a null point is generated. The standing wave generated on the communication sheet includes a standing wave generated in the first direction (longitudinal direction of the communication sheet) and a standing wave generated in the second direction (width direction of the communication sheet). is there. Here, for example, Patent Document 1 discloses a technique in which an electromagnetic wave absorbing medium extending in the second direction is provided at an end portion in the first direction in order to reduce standing waves generated in the first direction. ing. Patent Document 1 discloses a technique for resonating an electromagnetic wave in the second direction by actively reflecting the electromagnetic wave at an end in the second direction.

Japanese Patent No. 5399686

  However, it is unclear whether the technique disclosed in Patent Document 1 can suppress the occurrence of a null point in the second direction. Moreover, in the technique disclosed in Patent Document 1, it is necessary to make the width of the communication sheet in the second direction equal to a natural number multiple of half of the wavelength of the electromagnetic wave, so that the width of the communication sheet can be freely designed. Can not. For this reason, a communication sheet that realizes stable communication while maintaining the degree of freedom of the width of the communication sheet is desired.

  The present invention has been made in view of the above problems, and an object thereof is to provide a communication sheet that realizes stable communication while maintaining the degree of freedom of the width of the communication sheet.

In order to achieve the above object, a communication sheet according to the present invention includes:
A first conductor layer having a mesh-shaped opening, a second conductor layer, and an insulator layer provided between the first conductor layer and the second conductor layer; An electromagnetic wave generating unit that generates an electromagnetic wave corresponding to an electric signal, and a communication sheet comprising:
When the communication sheet is viewed from the thickness direction, the shape is two long sides extending in the longitudinal direction orthogonal to the thickness direction, and two short sides extending in the width direction orthogonal to the thickness direction and the longitudinal direction. A rectangle including sides,
The electromagnetic wave generation unit is provided on one short side portion of the two short sides,
The first conductor layer includes a slit extending in the longitudinal direction from the one short side.

  The distance in the width direction from the electromagnetic wave generation unit to the slit may be ¼ of the wavelength of the electromagnetic wave.

  The length of the slit in the longitudinal direction may be 1/4 of the wavelength of the electromagnetic wave.

  The length of the slit in the width direction may be longer than 1/50 of the wavelength of the electromagnetic wave.

The electromagnetic wave generation unit is provided in a central portion of the one short side,
Two slits may be provided at positions sandwiching the electromagnetic wave generation unit with the electromagnetic wave generation unit as a center.

  ADVANTAGE OF THE INVENTION According to this invention, stable communication is realizable, maintaining the freedom degree of the width | variety of a communication sheet.

Configuration diagram of a communication system according to an embodiment of the present invention The top view of the communication sheet which concerns on embodiment of this invention Sectional view of the AA line in FIG. Diagram showing slit size and arrangement Explanatory drawing of the technique to measure the intensity of electromagnetic waves radiated from the communication sheet It is a figure which shows the measurement result of a reflection coefficient, (A) is a figure which shows the measurement result of the reflection coefficient in the 1st condition, (B) is a figure which shows the measurement result of the reflection coefficient in the 2nd condition It is a figure which shows the measurement result of a reflection coefficient, (A) is a figure which shows the measurement result of the reflection coefficient in the 3rd condition, (B) is a figure which shows the measurement result of the reflection coefficient in the 4th condition It is a figure which shows the measurement result of a reflection coefficient, (A) is a figure which shows the measurement result of the reflection coefficient in the 5th condition, (B) is a figure which shows the measurement result of the reflection coefficient in the 6th condition It is a figure which shows the measurement result of a reflection coefficient, (A) is a figure which shows the measurement result of the reflection coefficient in the 7th condition, (B) is a figure which shows the measurement result of the reflection coefficient in the 8th condition

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals.

(Embodiment)
FIG. 1 is a configuration diagram of a communication system 1000 according to an embodiment of the present invention. The communication system 1000 is a system in which the control device 500 communicates with the wireless tag 610 via the communication sheet 100. Specifically, the communication system 1000 is a system that reads tag information from a wireless tag 610 attached to an article 600 placed on the communication sheet 100 by the control device 500 controlling the reader / writer 400. The communication system 1000 is also a system in which tag information is written in the wireless tag 610 attached to the article 600 arranged on the communication sheet 100 by the control device 500 controlling the reader / writer 400. The communication system 1000 includes a communication sheet 100, a reader / writer 400, a control device 500, and an article 600.

  The communication sheet 100 is a communication sheet for realizing two-dimensional communication. The communication sheet 100 propagates electromagnetic waves used in two-dimensional communication. The communication sheet 100 has a function of leaking the electromagnetic wave supplied from the reader / writer 400 from the surface of the communication sheet 100 while propagating in the XY plane direction. The communication sheet 100 supplies the electromagnetic wave supplied from the electromagnetic wave interface 200 to the wireless tag 610 (hereinafter, appropriately referred to as “electromagnetic wave transmission function”) and supplies the electromagnetic wave supplied from the wireless tag 610 to the electromagnetic wave interface 200. Function (hereinafter referred to as “electromagnetic wave receiving function” as appropriate). In the present embodiment, the electromagnetic wave transmission function will be basically described.

  The shape of the communication sheet 100 is such that the length in the longitudinal direction (hereinafter simply referred to as “longitudinal direction”) of the communication sheet 100 is the length (width) in the width direction (hereinafter simply referred to as “width direction”) of the communication sheet 100. ) And a length in the width direction that is sufficiently longer than the length (thickness) in the thickness direction of the communication sheet 100 (hereinafter simply referred to as “thickness direction”). The longitudinal direction, the width direction, and the thickness direction are orthogonal to each other. In this embodiment, the longitudinal direction is the X-axis direction, the width direction is the Y-axis direction, and the thickness direction is the Z-axis direction. Note that the X-axis direction, the Y-axis direction, and the Z-axis direction are orthogonal to each other. The X-axis direction and the Y-axis direction are directions parallel to the horizontal plane. The Z-axis direction is the vertical direction. When the communication sheet 100 is viewed from the thickness direction, the shape is a rectangle composed of two long sides extending in the longitudinal direction and two short sides extending in the width direction. The communication sheet 100 includes an electromagnetic wave interface 200 and an electromagnetic wave absorber 300 described later.

  The electromagnetic wave interface 200 converts the electric signal supplied from the reader / writer 400 into an electromagnetic wave and supplies it to the communication sheet 100 (hereinafter referred to as “electromagnetic wave transmission function” as appropriate), and the electromagnetic wave supplied from the communication sheet 100. And a function of converting it into an electrical signal and supplying it to the reader / writer 400 (hereinafter referred to as “electromagnetic wave receiving function” as appropriate).

  The electromagnetic wave transmission function is a function used when writing tag information in the wireless tag 610 or supplying power to the wireless tag 610. That is, when the electromagnetic wave interface 200 writes tag information in the wireless tag 610, the electromagnetic wave interface 200 receives an electric signal including the tag information from the reader / writer 400 and injects an electromagnetic wave including the tag information into the communication sheet 100. Further, when supplying power to the wireless tag 610, the electromagnetic wave interface 200 receives an electric signal for supplying power from the reader / writer 400 and injects an electromagnetic wave for supplying power into the communication sheet 100. Note that when the wireless tag 610 is a passive tag, power needs to be supplied to the wireless tag 610 before tag information is read from the wireless tag 610.

  The electromagnetic wave receiving function is a function used when reading tag information from the wireless tag 610. That is, when reading the tag information from the wireless tag 610, the electromagnetic wave interface 200 receives the electromagnetic wave including the tag information from the communication sheet 100, and transmits an electric signal including the tag information to the reader / writer 400. The electromagnetic wave interface 200 is preferably provided at the center of one of the two short sides of the rectangle formed by the communication sheet 100. In the present embodiment, a portion where the electromagnetic wave interface 200 is provided in the communication sheet 100 is appropriately referred to as a feeding point.

  Here, when power is supplied to the wireless tag 610, the electromagnetic wave supplied from the electromagnetic wave interface 200 to the communication sheet 100 is leached from the surface of the communication sheet 100 in the process of propagating in the longitudinal direction while spreading in the width direction. Here, in order to realize stable communication, it is desirable that the electromagnetic wave leaches uniformly over the entire surface of the communication sheet 100. However, a standing wave is generated when the electromagnetic wave is reflected at the end of the communication sheet 100. The electromagnetic wave becomes strong at the antinode of the standing wave, but the electromagnetic wave becomes extremely weak at the node of the standing wave. A portion where the electromagnetic wave becomes extremely weak is appropriately referred to as a null point.

  Here, the standing wave generated on the communication sheet 100 includes a standing wave generated in the longitudinal direction and a standing wave generated in the width direction. The standing wave generated in the longitudinal direction is generated when the electromagnetic wave traveling in the longitudinal direction is reflected by at least one of the two short sides of the rectangle formed by the communication sheet 100. Further, the standing wave generated in the width direction is generated when the electromagnetic wave traveling in the width direction is reflected by at least one of the two long sides of the rectangle formed by the communication sheet 100. Standing waves generated in the longitudinal direction generate null points arranged along the longitudinal direction. The standing wave generated in the width direction generates null points arranged along the width direction.

  In order to prevent the null point from occurring, it is preferable to prevent the standing wave from occurring. In order to prevent the standing wave from being generated, it is preferable that the electromagnetic wave is not reflected at the end of the communication sheet 100. Therefore, in the present embodiment, the electromagnetic wave absorber 300 is provided in the central portion of the other short side of the two rectangular short sides that the communication sheet 100 configures.

  The electromagnetic wave absorber 300 absorbs electromagnetic waves and converts them into thermal energy. The electromagnetic wave absorber 300 is provided at the central portion of the other short side of the rectangle formed by the communication sheet 100 (the short side opposite to the short side provided with the feeding point). In the present embodiment, the length of the electromagnetic wave absorber 300 in the width direction (Y-axis direction) is shorter than the length of the communication sheet 100 in the width direction (Y-axis direction). As shown in FIG. 3, the electromagnetic wave absorber 300 is fixed on the communication sheet 100 by the metal tape 310 while being placed on the center portion of the other short side of the surface of the communication sheet 100. The metal tape 310 is bent so that the adhesive surface straddles the end of the communication sheet 100 and sandwiches the electromagnetic wave absorber 300 and the communication sheet 100, and is pasted from the front surface to the back surface of the communication sheet 100.

  Here, the protective film 140 exists between the first conductor layer 110 and the metal tape 310, and the protective film 150 exists between the second conductor layer 120 and the metal tape 310. However, the current flowing through the first conductor layer 110 and the second conductor layer 120 is a high-frequency alternating current. Therefore, the current travels between the first conductor layer 110 and the metal tape 310, and also travels between the second conductor layer 120 and the metal tape 310. As a result, current can travel between the first conductor layer 110 and the second conductor layer 120 via the metal tape 310. For this reason, the electromagnetic wave absorber 300 not only absorbs the current flowing through the first conductor layer 110 but also absorbs the current flowing through the metal tape 310. That is, the electromagnetic wave absorber 300 can efficiently absorb energy. Due to the action of the electromagnetic wave absorber 300, the reflection of the electromagnetic wave at the other short side of the rectangle formed by the communication sheet 100 is reduced. As a result, standing waves generated in the longitudinal direction are suppressed, and generation of null points arranged along the longitudinal direction is suppressed.

  Here, in order to suppress generation | occurrence | production of the null point arranged along the width direction, there exists the method of providing the electromagnetic wave absorber 300 in two long sides of the rectangle which the communication sheet 100 comprises. However, the length of the communication sheet 100 in the longitudinal direction is longer than the length of the communication sheet 100 in the width direction. Therefore, when this direction is adopted, it is desirable to provide a large number of electromagnetic wave absorbers 300 or to provide an electromagnetic wave absorber 300 that is long in the longitudinal direction. However, when such an electromagnetic wave absorber 300 is provided, not only the manufacturing cost of the communication sheet 100 increases, but also the size and weight of the communication sheet 100 increase. Furthermore, when such an electromagnetic wave absorber 300 is provided, many electromagnetic waves are absorbed in the two long sides of the rectangle formed by the communication sheet 100, and the electromagnetic waves leached from the entire surface of the communication sheet 100 are weakened. As a result, stable communication cannot be performed, or power consumption increases.

  Therefore, in the present embodiment, the short side where the feeding point is provided on the first conductor layer 110 provided in the communication sheet 100 without providing the electromagnetic wave absorber 300 on the two long sides of the rectangle formed by the communication sheet 100. A method of providing a slit 111 extending in the longitudinal direction from the head is adopted. According to the method of providing the slit 111 in the first conductor layer 110, it can be expected to suppress the generation of null points arranged along the width direction without absorbing much electromagnetic waves. The reason is that, for example, the electromagnetic wave traveling in the width direction is separated into a component traveling in the longitudinal direction (negative direction of the X axis) and a component traveling in the width direction by the slit 111, It can be mentioned that generation of a standing wave having a large amplitude in the width direction is suppressed by canceling out the components. The component traveling forward in the longitudinal direction (the negative direction of the X axis) is reflected at the end on the near side in the longitudinal direction of the communication sheet 100 and back in the longitudinal direction (positive direction of the X axis). Change the direction to counteract with the component proceeding in the width direction. That is, by providing the slit 111 whose length in the longitudinal direction is 1/4 of the wavelength of the electromagnetic wave, an open stub whose length in the longitudinal direction is 1/4 of the wavelength of the electromagnetic wave is formed in the region outside the slit 111. It can be considered that it is formed.

  The reader / writer 400 reads tag information from the wireless tag 610 or writes tag information to the wireless tag 610 in accordance with control by the control device 500. The reader / writer 400 is connected to a communication interface provided in the control device 500 via a communication cable (not shown). The reader / writer 400 is connected to the electromagnetic wave interface 200 via the communication cable 410. When the reader / writer 400 receives information instructing reading of tag information from the control device 500, the reader / writer 400 transmits an electric signal corresponding to the electromagnetic wave for power supply to the electromagnetic wave interface 200. When the electromagnetic wave interface 200 receives an electromagnetic wave including tag information, the reader / writer 400 receives an electric signal corresponding to the electromagnetic wave from the electromagnetic wave interface 200. The reader / writer 400 transmits tag information indicated by the received electrical signal to the control device 500. Further, when the reader / writer 400 receives information instructing writing of tag information from the control device 500, the reader / writer 400 transmits an electric signal including the tag information to the electromagnetic wave interface 200.

  The communication cable 410 is a cable for connecting the reader / writer 400 and the electromagnetic wave interface 200. The communication cable 410 is a coaxial cable including a signal line and a ground line, for example. A connector 420 is provided at one end of the communication cable 410. The connector 420 has a function of connecting the communication cable 410 and the electromagnetic wave interface 200.

  The control device 500 controls reading and writing of tag information by the reader / writer 400. The control device 500 instructs the reader / writer 400 to read the tag information via a communication cable (not shown), and receives the read tag information from the reader / writer 400. Also, the control device 500 instructs the reader / writer 400 to write tag information via a communication cable (not shown). The control device 500 is a terminal device such as a notebook computer, a tablet terminal, or a smartphone. Therefore, the control device 500 includes, for example, a CPU (Central Processing Unit) not shown, a ROM (Read Only Memory) not shown, a RAM (Random Access Memory) not shown, a flash memory not shown, an RTC (Real Time Clock) not shown, A touch screen (not shown) and a communication interface (not shown) are provided.

  The article 600 is an article to be managed. The article 600 is, for example, a book or a tool. A wireless tag 610 is attached to the article 600. The wireless tag 610 is attached to the article 600 by, for example, a double-sided tape. When the wireless tag 610 stores tag information and receives an electromagnetic wave for supplying power, the wireless tag 610 emits an electromagnetic wave including the tag information. That is, the wireless tag 610 is a passive tag and is an RFID (Radio Frequency IDentification) tag. The tag information is identification information for identifying the article 600, for example. The identification information is information indicating a character string composed of numerical values and alphabets, for example. The frequency of the electromagnetic wave received or transmitted by the wireless tag 610 is a UHF band frequency, for example, 920 MHz.

  FIG. 2 is a plan view when the communication sheet 100 is viewed from the positive direction of the Z-axis direction. As shown in FIG. 2, the communication sheet 100 includes a mesh-shaped first conductor layer 110 having a number of equilateral triangular openings. The communication sheet 100 having such a mesh pattern has a very high radio wave intensity in the vicinity of the communication sheet 100, while the radio wave intensity at a location away from the communication sheet 100 is very low. For this reason, the communication sheet 100 is suitable for communicating with a communication partner having a relatively low antenna sensitivity. That is, the communication sheet 100 is suitable for reading an RFID tag.

  In this embodiment, BLx which is the length in the longitudinal direction of the communication sheet 100 is 800 mm, and BLy which is the length in the width direction of the communication sheet 100 is 300 mm. The first conductor layer 110 included in the communication sheet 100 includes a slit 111A and a slit 111B. Hereinafter, the slit 111A and the slit 111B are collectively referred to as the slit 111 as appropriate. In addition, when forming the slit 111 in the conductor layer 110, for example, from the surface of the communication sheet 100 (the larger surface of the communication sheet 100, the surface having the larger Z-axis coordinate), the protective film 140 and the first film The corresponding portion of the conductor layer 110 may be removed. That is, when the slit 111 is formed, the insulator layer 130, the second conductor layer 120, and the protective film 150 may not be processed. The size and arrangement of the slit 111 will be described later.

  FIG. 3 is a sectional view taken along line AA in FIG. As shown in FIG. 3, the communication sheet 100 includes a protective film 140, a first conductor layer 110, an insulator layer 130, a second conductor layer 120, and a protective film 150 in order from the largest coordinate in the Z-axis direction. Overlaid and configured.

  The first conductor layer 110 is a layer made of a conductor and having mesh openings. The first conductor layer 110 has a function of causing the electromagnetic wave propagating inside the communication sheet 100 to leak out from the opening and forming the leaching region 160. The first conductor layer 110 has, for example, a plurality of linear conductors extending in the X-axis direction, an angle of 60 degrees with respect to the X-axis, an angle of 30 degrees with respect to the Y-axis, and an XY plane A plurality of linear conductors extending in a first axial direction parallel to the first axis, and a plurality of linear conductors having an angle of 60 degrees with respect to the first axis and extending in a second axial direction parallel to the XY plane; Are layers in which a plurality of equilateral triangular openings are formed by crossing each other. In this embodiment, the length of one side of the equilateral triangle is 12.7 mm.

  The second conductor layer 120 is a flat layer made of a conductor. The second conductor layer 120 has a function of suppressing electromagnetic waves propagating through the communication sheet 100 from leaking from the back surface of the communication sheet 100. The size (the length in the X-axis direction, the length in the Y-axis direction, the length in the Z-axis direction) of the first conductor layer 110 and the second conductor layer 120 is, for example, 800 mm × 300 mm × 0.032 mm. . The 1st conductor layer 110 and the 2nd conductor layer 120 are comprised by metals, such as gold | metal | money, silver, copper, aluminum, iron, various alloys, for example.

  The insulator layer 130 is a layer made of an insulator (dielectric material). The insulator layer 130 has a function of propagating electromagnetic waves radiated from the communication device 100 in the direction in which the communication sheet 100 spreads, that is, in the XY plane direction. The insulator layer 130 is preferably an insulator having a low dielectric constant corresponding to the frequency (for example, 920 MHz) of an electromagnetic wave used for communication. For example, the insulator layer 130 is made of foamed polyolefin. The size of the insulator layer 130 is, for example, 800 mm × 300 mm × 1 mm.

  The protective film 140 is a layer composed of an insulator. The protective film 140 has a function of suppressing the surface of the first conductor layer 110 from being damaged or the surface of the first conductor layer 110 from coming into contact with an external conductor. The protective film 150 is a layer composed of an insulator. The protective film 150 has a function of suppressing the surface of the second conductor layer 120 from being damaged or the back surface of the second conductor layer 120 from coming into contact with an external conductor. The protective film 140 and the protective film 150 are made of, for example, PET (polyethylene terephthalate).

  The leaching region 160 is a region where electromagnetic waves propagating through the communication sheet 100 leak from the surface of the communication sheet 100. That is, the communication sheet 100 localizes the electromagnetic wave radiated from the communication device 100 in the leaching region 160. When the article 600 attached with the wireless tag 610 that is the communication partner of the communication device 100 is placed on the surface of the communication sheet 100 and the wireless tag 610 is in the leaching area 160, the communication device 100 and the wireless tag 610 Communication becomes possible. Here, when the length of the leaching region 160 in the Z-axis direction does not depend on the X-axis coordinate and the Y-axis coordinate and is constant, stable communication can be expected.

  The electromagnetic wave interface 200 includes a first electrode 210, a second electrode 220, and a dielectric 230. The electromagnetic wave interface 200 is configured such that the first electrode 210 and the second electrode 220 sandwich the dielectric 230 and the communication sheet 100. The first electrode 210 and the second electrode 220 are flat electrodes made of a conductor. The dielectric 230 is made of a dielectric. A signal line included in the communication cable 410 is connected to the first electrode 210. A ground line included in the communication cable 410 is connected to the second electrode 220. The electromagnetic wave interface 200 generates an electromagnetic wave corresponding to the electrical signal received from the reader / writer 400 between the first electrode 210 and the second electrode 220 and injects the generated electromagnetic wave into the communication sheet 100. The electromagnetic wave interface 200 generates an electric signal corresponding to the electromagnetic wave (electromagnetic wave generated between the first electrode 210 and the second electrode 220) supplied from the communication sheet 100, and the generated electric signal is generated. The data is transmitted to the reader / writer 400. The size, shape, and material of the first electrode 210, the second electrode 220, and the dielectric 230 are determined by, for example, the frequency of electromagnetic waves used for communication.

  As shown in FIG. 3, the electromagnetic wave absorber 300 is a member having a U-shaped cross section. The electromagnetic wave absorber 300 is disposed so as to sandwich the communication sheet 100. In the present embodiment, it is assumed that the electromagnetic wave absorber 300 is detachable from the communication sheet 100.

  Next, the size and position of the slit 111A will be described with reference to FIG. The size of the slit 111B is basically the same as the size of the slit 111A. In addition, the electromagnetic wave interface 200 is disposed at an intermediate point between the position of the slit 111A and the position of the slit 111B. That is, the slit 111B is arranged at a position that is symmetrical with the slit 111A with a center line that is parallel to the X-axis and passes through the center of the electromagnetic wave interface 200 as an axis of symmetry.

  The slit 111A is a notch extending in the positive direction of the X axis from the short side where the feeding point is provided. The length of the slit 111A in the X-axis direction is SLx, and the length of the slit 111A in the Y-axis direction is SLy. Here, when the slit 111A is a trapezoid whose upper base and lower base are parallel to the X-axis direction, SLx is an average value of SLSx and SLLx. SLSx is the shorter of the upper and lower bases. SLLx is the longer of the upper and lower bases.

  Here, the distance from the electromagnetic wave interface 200 to the slit 111A (the distance from the portion closest to the slit 111A in the first electrode 210 to the portion closest to the first electrode 210 in the slit 111A) is defined as SDy. The distance from the feeding point to the slit 111A (the distance from the center of the first electrode 210 in the Y-axis direction to the portion closest to the feeding point in the slit 111A) is SD2y. When viewed from the Z-axis direction, the electromagnetic wave interface 200 (the first electrode 210 and the second electrode 220) is relatively wide in the Y-axis direction and relatively long in the Y-axis direction. It is assumed that the short narrow portion is a convex shape connected so as to be line symmetric with respect to an axis of symmetry parallel to the X axis. In addition, the junction part of a wide part and a narrow part overlaps with one short side of two short sides of the rectangle which the communication sheet 100 comprises. Here, the length of the wide portion in the Y-axis direction is EL1y, the length of the narrow portion in the Y-axis direction is EL2y, and the step between the wide portion and the narrow portion is EL3y = (EL1y−EL2y) / 2. In this embodiment, it is assumed that EL1y = 27 mm, EL2y = 22 mm, and EL3y = 2.5 mm.

  The inventors of the present application have found the size and position of the slit 111 that can effectively suppress the occurrence of null points aligned in the Y-axis direction by measuring the electromagnetic waves radiated from the communication sheet 100.

  First, it is preferable that the width of the slit 111 (the length of the slit 111 in the Y-axis direction) is not too short with respect to the wavelength of the electromagnetic wave. This is because when the width of the slit 111 is too short with respect to the wavelength of the electromagnetic wave, the electromagnetic wave easily jumps over the slit 111 and the effect obtained by the slit 111 is small. For example, the width of the slit 111 is preferably about 1/50 or more of the wavelength of the electromagnetic wave. In the present embodiment, the frequency of the electromagnetic wave is 920 MHz, and the wavelength of the electromagnetic wave is 325 mm. Therefore, the width of the slit 111 is preferably 7 mm or more. That is, regarding the slit 111A, SLy is preferably 7 mm or more. The opening period of the mesh is designed to be appropriately short with respect to the wavelength of the electromagnetic wave so that the electromagnetic wave can jump over the opening appropriately. In this embodiment, as described above, the mesh opening period (the length of one side of the equilateral triangle) is 12.7 mm.

  The length of the slit 111 (the length of the slit 111 in the X-axis direction) is preferably about ¼ of the wavelength of the electromagnetic wave. In addition, when the length of the slit 111 is too short, it is thought that the effect obtained by the slit 111 is small. On the other hand, when the length of the slit 111 is too long, the electromagnetic wave hardly propagates in the Y-axis direction. In the present embodiment, the length of the slit 111 is preferably about 80 mm. That is, regarding the slit 111A, SLx is preferably about 80 mm.

  The distance from the first electrode 210 to the slit 111 is preferably about 1/4 of the wavelength of the electromagnetic wave. Note that when the distance from the first electrode 210 to the slit 111 is changed, the position in the X-axis direction where the null points arranged in the Y-axis direction are generated changes. In the present embodiment, the distance from the first electrode 210 to the slit 111 is preferably about 80 mm. That is, regarding the slit 111A, it is preferable that SDy is about 80 mm and SD2y (SDy + EL1y / 2) is about 93.5 mm.

  Next, a method for measuring the intensity of electromagnetic waves radiated from the communication sheet 100 will be described with reference to FIG. In this embodiment, an example in which the strength of electromagnetic waves is measured by the network analyzer 700 will be described.

  The network analyzer 700 measures the transmission characteristics of a plurality of measurement points 810 that are arranged in a square lattice pattern at regular intervals on the measurement surface 800. The measurement surface 800 is a surface obtained by shifting the surface of the communication sheet 100 (the surface of the two surfaces of the protective film 140 that does not contact the first conductor layer 110) by VDz in the positive direction of the Z axis. That is, the measurement surface 800 and the surface of the communication sheet 100 are parallel, and the distance from the measurement surface 800 to the surface of the communication sheet 100 is VDz. The plurality of measurement points 810 are arranged at intervals of the PD in both the X-axis direction and the Y-axis direction. In the present embodiment, VDz is 30 mm and PD is 20 mm.

  In this embodiment, the transmission characteristic is measured by S21 out of the S parameters. The S parameter is a scattering parameter. S 21 is the amount of change in the magnitude and phase of the transmission signal with respect to the incident signal, and is a signal that is transmitted to the terminal 760 when the signal is incident on the terminal 730. S21 is represented by an absolute value, and its unit is dB. That is, the measurement point 810 having a larger value of S21 has a larger amount of electromagnetic wave radiation. A measurement point 810 having a very small value of S21 can be said to be a null point.

  The network analyzer 700 includes a terminal 730 and a terminal 760. The terminal 730 and the electromagnetic wave interface 200 are connected to each other by a cable 710. The cable 710 and the electromagnetic wave interface 200 are connected by a connector 720 included in the cable 710. The first electrode 210 is connected to a signal line (not shown) included in the cable 710. The second electrode 220 is connected to a ground line (not shown) included in the cable 710.

  One end of a cable 740 is connected to the terminal 760. A probe 750 is provided at the other end of the cable 740. The probe 750 sequentially scans the measurement points 810 provided in a lattice shape by a mechanism (not shown).

  Hereinafter, the distribution of S21 measured by the network analyzer 700 will be described. FIG. 6A shows the distribution of S21 under the first condition. FIG. 6B is a diagram showing the distribution of S21 under the second condition. FIG. 7A is a diagram illustrating the distribution of S21 under the third condition. FIG. 7B is a diagram showing the distribution of S21 under the fourth condition. FIG. 8A shows the distribution of S21 under the fifth condition. FIG. 8B is a diagram showing the distribution of S21 under the sixth condition. FIG. 9A shows the distribution of S21 under the seventh condition. FIG. 9B is a diagram illustrating the distribution of S21 in the eighth condition.

  The first condition is that the slit 111 is not provided in the first conductor layer 110 and the electromagnetic wave absorber 300 is not provided. The second condition is that the slit 111 is not provided in the first conductor layer 110 but the electromagnetic wave absorber 300 is provided. The third condition is that SD2y is 80 mm (SDy is 66.5 mm) and the electromagnetic wave absorber 300 is not provided. The fourth condition is that SD2y is 80 mm (SDy is 66.5 mm) and the electromagnetic wave absorber 300 is provided. The fifth condition is that SD2y is 90 mm (SDy is 76.5 mm), and the electromagnetic wave absorber 300 is not provided. The sixth condition is that SD2y is 90 mm (SDy is 76.5 mm) and the electromagnetic wave absorber 300 is provided. The seventh condition is that SD2y is 100 mm (SDy is 86.5 mm), and the electromagnetic wave absorber 300 is not provided. The eighth condition is that SD2y is 100 mm (SDy is 86.5 mm) and the electromagnetic wave absorber 300 is provided.

  In FIG. 6A, FIG. 6B, FIG. 7A, FIG. 7B, FIG. 8A, FIG. 8B, FIG. 9A, and FIG. The point where the point occurs is indicated by a solid circle. First, as shown in FIG. 6A, under the first condition, not only null points arranged in the X-axis direction but also null points arranged in the Y-axis direction are generated. Under the first condition, there are many null points arranged in the X-axis direction and the Y-axis direction on the surface of the communication sheet 100, and it is difficult to realize stable communication. On the other hand, as shown in FIG. 6B, under the second condition, the generation of null points arranged in the X-axis direction is slightly suppressed, but the null points arranged in the Y-axis direction are generated. Under the second condition, there are null points arranged in the Y-axis direction on the surface of the communication sheet 100, and it is difficult to realize stable communication.

  Next, as shown in FIG. 7A, under the third condition, null points aligned in the X-axis direction are generated, but generation of null points aligned in the Y-axis direction is suppressed to some extent. Under the third condition, since there are few null points arranged in the Y-axis direction on the surface of the communication sheet 100, it is possible to realize communication that is stable to some extent. On the other hand, as shown in FIG. 7B, under the fourth condition, the generation of null points aligned in the X-axis direction is slightly suppressed, and the generation of null points aligned in the Y-axis direction is also suppressed to some extent. Under the fourth condition, since there are few null points arranged in the X-axis direction and null points arranged in the Y-axis direction on the surface of the communication sheet 100, further stable communication can be realized.

  Next, as shown in FIG. 8A, under the fifth condition, null points aligned in the X-axis direction are generated, but generation of null points aligned in the Y-axis direction is suppressed. In particular, in the fifth condition, the occurrence of null points aligned in the Y-axis direction is considerably suppressed in the central portion of the communication sheet 100 in the X-axis direction. However, in the fifth condition, the occurrence of null points aligned in the Y-axis direction is not significantly suppressed in the right side portion (terminal portion) of the communication sheet 100 in the X-axis direction. Under the fifth condition, since the number of null points arranged in the Y-axis direction on the surface of the communication sheet 100 is considerably small, stable communication can be realized. On the other hand, as shown in FIG. 8B, under the sixth condition, the generation of null points aligned in the X-axis direction is slightly suppressed, and the generation of null points aligned in the Y-axis direction is also suppressed. In particular, in the sixth condition, the occurrence of null points aligned in the Y-axis direction is considerably suppressed in the central portion of the communication sheet 100 in the X-axis direction. However, in the sixth condition, the occurrence of null points aligned in the Y-axis direction is not significantly suppressed in the right side portion (terminal portion) of the communication sheet 100 in the X-axis direction. Under the sixth condition, the number of null points arranged in the X-axis direction and null points arranged in the Y-axis direction on the surface of the communication sheet 100 is considerably small, so that more stable communication can be realized.

  Next, as shown in FIG. 9A, under the seventh condition, null points aligned in the X-axis direction are generated, but generation of null points aligned in the Y-axis direction is suppressed. In particular, under the seventh condition, the occurrence of null points aligned in the Y-axis direction is considerably suppressed in the central portion of the communication sheet 100 in the X-axis direction. Under the seventh condition, the number of null points arranged in the Y-axis direction on the surface of the communication sheet 100 is considerably small, so that stable communication can be realized. On the other hand, as shown in FIG. 9B, under the eighth condition, the generation of null points aligned in the X-axis direction is slightly suppressed, and the generation of null points aligned in the Y-axis direction is also suppressed. In particular, in the eighth condition, the occurrence of null points aligned in the Y-axis direction is considerably suppressed in the central portion of the communication sheet 100 in the X-axis direction. Under the eighth condition, the number of null points arranged in the X-axis direction and null points arranged in the Y-axis direction on the surface of the communication sheet 100 is considerably small, so that more stable communication can be realized.

  As described above, by providing the slit 111 in the first conductor layer 110, it is possible to suppress the occurrence of null points arranged in the Y-axis direction. In particular, when the length from the electromagnetic wave interface 200 to the slit 111 is set to about 1/4 of the wavelength of the electromagnetic wave (from the fifth condition to the eighth condition), the effect of suppressing the generation of null points is enhanced. In addition, by providing the electromagnetic wave absorber 300 on the short side opposite to the short side having the feeding point, it is possible to suppress the occurrence of null points arranged in the X-axis direction.

  In this embodiment, generation | occurrence | production of the null point which generate | occur | produces on the communication sheet 100 can be suppressed. Therefore, according to the present embodiment, stable communication can be realized.

  The communication sheet 100 according to the present embodiment can be used in various systems including, for example, a wireless tag, a reader / writer, a control device, and a display device. For example, the communication sheet 100 can be used for an article management system, a progress / process management system, a sales secret management system, and a product promotion system (marketing system). Articles managed in the article management system include, for example, medical materials (ME (Medical Engineering) equipment, medical equipment, catheters, etc.) used in hospitals, pallets, products and tools in factories and warehouses, merchandise in retail and distribution, Books held by libraries, confidential documents held by companies (contracts, design drawings, etc.), IT (Information Technology) equipment held by companies, and the like. In the article management system, for example, by placing an article with a wireless tag attached on the communication sheet 100, the inventory of the article, the location of the article, the use status of the article, and the like are managed. Note that the communication sheet 100 on which the articles are arranged may be laid in a shelf or a drawer.

  The progress / process management system, for example, manages data related to progress by reading tag information held by a wireless tag affixed to a work instruction sheet, assembly parts, or the like using a communication sheet 100 in a production factory. System. The business secret management system is a system that displays a work process chart on a display device only when an operator places a specific wireless tag on the communication sheet 100, for example. The product promotion system (marketing system), for example, grasps customer preferences from the history of products taken by consumers, formulates optimal promotion campaign plans, and promotes sales by pre-reading consumer behavior. System. In addition, the history that the product was taken by the consumer is acquired by, for example, using the communication sheet 100 by attempting to read the tag information held by the wireless tag attached to the product. For example, when certain tag information cannot be read temporarily (for example, for only 10 seconds), it can be considered that a product to which a wireless tag having the tag information is attached is taken by the consumer.

(Modification)
As mentioned above, although embodiment of this invention was described, when implementing this invention, a deformation | transformation and application with a various form are possible.

  In the present invention, which part of the configuration, function, and operation described in the above embodiment is adopted is arbitrary. Further, in the present invention, in addition to the configuration, function, and operation described above, further configuration, function, and operation may be employed. Further, the above-described embodiments can be freely combined as appropriate. Of course, materials, sizes, electrical characteristics, and the like that can be employed in the present invention are not limited to those shown in the above embodiment.

  In the embodiment, an example in which the shape of the mesh-shaped opening is an equilateral triangle has been described. In the present invention, the shape of the mesh-shaped opening is of course not limited to a regular triangle. The shape of the mesh-shaped opening may be, for example, a triangle other than a regular triangle, a polygon other than a triangle (rectangle, square, parallelogram, rhombus, pentagon, hexagon, etc.), circle, ellipse, or the like. .

  In the embodiment, an example in which a frequency for RFID (920 MHz) is employed as the frequency of electromagnetic waves has been described. Of course, the frequency of the electromagnetic wave employed in the present invention is not limited to this frequency. For example, a frequency (2.45 GHz) for WiFi or Bluetooth (registered trademark) can be used.

  In the embodiment, for easy understanding, the wavelength of the electromagnetic wave is obtained from the frequency of the electromagnetic wave, assuming that the electromagnetic wave is in a vacuum. However, the wavelength of the electromagnetic wave propagating through the communication sheet 100 is shorter than the wavelength of the electromagnetic wave propagating through the vacuum. Therefore, when the relative dielectric constant in the communication sheet 100 is so large that it cannot be identified with 1, the wavelength of the electromagnetic wave needs to be estimated smaller than the wavelength of the electromagnetic wave in vacuum.

100, 170 communication sheet, 110 first conductor layer, 111, 111A, 111B, 111C, 111D slit, 120 second conductor layer, 130 insulator layer, 140, 150 protective film, 160 leaching area, 200 electromagnetic wave interface, 210 first electrode, 220 second electrode, 230 dielectric, 300 electromagnetic wave absorber, 310 metal tape, 400 reader / writer, 410 communication cable, 420, 720 connector, 500 control device, 600 article, 610 wireless tag, 700 Network analyzer, 710, 740 cable, 730, 760 terminal, 750 probe, 800 measurement surface, 810 measurement point, 1000 communication system

Claims (5)

A first conductor layer having a mesh-shaped opening, a second conductor layer, and an insulator layer provided between the first conductor layer and the second conductor layer; An electromagnetic wave generating unit that generates an electromagnetic wave corresponding to an electric signal, and a communication sheet comprising:
When the communication sheet is viewed from the thickness direction, the shape is two long sides extending in the longitudinal direction orthogonal to the thickness direction, and two short sides extending in the width direction orthogonal to the thickness direction and the longitudinal direction. A rectangle including sides,
The electromagnetic wave generation unit is provided on one short side portion of the two short sides,
The first conductor layer includes a slit extending in the longitudinal direction from the one short side,
Communication sheet. The distance in the width direction from the electromagnetic wave generator to the slit is 1/4 of the wavelength of the electromagnetic wave.
The communication sheet according to claim 1. The length of the slit in the longitudinal direction is 1/4 of the wavelength of the electromagnetic wave.
The communication sheet according to claim 1 or 2. The length of the slit in the width direction is longer than 1/50 of the wavelength of the electromagnetic wave.
The communication sheet according to any one of claims 1 to 3. The electromagnetic wave generation unit is provided in a central portion of the one short side,
Two slits are provided at positions sandwiching the electromagnetic wave generation unit with the electromagnetic wave generation unit as a center,
The communication sheet according to any one of claims 1 to 4.

Images