JP4700101B2 - Tag antenna - Google Patents

Description

  The present invention relates to a contactless tag antenna that transmits and receives to / from an RFID reader / writer.

  By using a UHF band (860 to 960 MHz) radio signal, a signal of about 1 W is transmitted from the reader / writer, the signal is received on the tag side, and a response signal is sent back to the reader / writer side again. A system that can be read by a reader / writer is called an RFID system. The communication distance depends on the tag antenna gain, the chip operating voltage, and the surrounding environment, but is about 3 m. The tag is composed of an antenna having a thickness of about 10 to 30 microns and an LSI chip connected to the antenna feeding point.

  FIG. 19 is a diagram for explaining a tag antenna used in a conventional RFID system. FIG. 20 is a diagram showing an equivalent circuit of the RFID tag antenna. FIG. 21 is a diagram illustrating an analysis example based on an admittance chart of a conventional tag antenna.

  As shown in FIG. 20, the LSI chip can be equivalently represented by a parallel connection of a resistor Rc (for example, 1200Ω) and a capacitance Cc (for example, 0.7 pF). On the admittance chart, it is represented by a position indicated by a circle in FIG. On the other hand, the antenna can be equivalently represented by a parallel connection of a resistance Ra (for example, 1000Ω) and an inductance La (for example, 40 nH). By connecting both in parallel, the capacitance and the inductance resonate, and as can be seen from the expression f0 = 1 / (2π√ (LC)) representing the resonance frequency, the antenna and the chip are matched at the desired resonance frequency f0. In this case, the received power is sufficiently supplied to the chip side.

  As a basic antenna used for the tag antenna, a full-length 145 mm dipole antenna shown in FIG. In this antenna, the dipole unit 10 is connected to the power supply unit 11, and power is extracted from the signal received by the dipole unit 10, and the power is supplied from the power supply unit 11 to the chip and the signal itself is transferred to the chip. However, as indicated by a triangle in FIG. 21, Ra = 72Ω and imaginary part = 0 at f = 953 MHz. However, since the radiation resistance Ra of the antenna necessary for the RFID tag antenna is as high as about 1000Ω, Ra needs to be increased. Therefore, a folded dipole antenna having a total length of about 145 mm as shown in FIG. 19B is used, and it is well known that it can be raised to about 300Ω to 1500Ω depending on the line width. . FIG. 19B is the same except that the dipole portion 10 of FIG. 19A is a folded dipole portion 10a. FIG. 21 shows an example where Ra = 1000Ω. Further, as shown in FIG. 19 (c), an imaginary number component having the same absolute value as that of the chip (Bc = ωCc) is obtained by rotating the counterclockwise on the admittance chart by connecting the inductance portion 12 in parallel to the folded dipole antenna (Ba = -1 / ωLa). The shorter the inductance length, the smaller the La value and the greater the amount of rotation. As a result, the imaginary component Bc of the chip and the imaginary component Ba of the antenna have the same magnitude and are canceled and resonate.

  This imaginary component cancellation is the most important factor in RFID tag antenna design. On the other hand, it is desirable that the resistance Rc of the chip and the antenna radiation resistance Ra match, but it is not necessary to match exactly, and if the ratio of the two is about twice or less, the antenna reception power is supplied to the chip without any problem. .

  The above is the basic design method of the RFID tag antenna. The basic antenna is designed so that Ra = 1000Ω at the design frequency f = 953 MHz and the imaginary part = 0, and the susceptance of the chip (Bc = ωCc; Inductance (Ba = 1 / ωLa; La = 40nH) having the same absolute value as Cc = 0.7pF) must be connected in parallel.

Refer to Non-Patent Document 1 for the dipole antenna.
"Antenna Engineering Handbook" The Institute of Electronics, Information and Communication Engineers Edited by Ohm Co., Ltd. ISBN 4-274-02677-9

  However, an antenna having a length of about 15 mm and a width of about 145 mm is too large to be practical and needs to be miniaturized. For example, an antenna that is reduced to half the card size (86 mm × 54 mm) or about a quarter is more practical. However, when the antenna is designed with the design method as described above when it is downsized, the resonance frequency at which the imaginary part = 0 is increased in inverse proportion to the downsizing of the antenna. Cannot be matched.

  The subject of this invention is providing the tag antenna which can be reduced in size.

  The tag antenna of the present invention is a tag antenna composed of a dipole antenna and a power feeding unit on which a chip is mounted. A dipole part having a length shorter than one half of the antenna resonance wavelength is provided at the center of the dipole part. It is characterized by having a power feeding portion provided and end portions provided with regions wider than the line width of the dipole portion at both ends of the dipole portion.

  A small tag antenna can be formed with an antenna length smaller than λ / 2 (the antenna resonance wavelength is λ), and a communication distance of about 60 to 75% of a standard folded antenna with a λ / 2 length is maintained. be able to. Furthermore, the cost of the antenna can be greatly reduced by removing unnecessary metal portions.

In the embodiment of the present invention, an imaginary part = 0 on the admittance chart by connecting an inductor in parallel to an RFID tag antenna having an antenna length shorter than λ / 2, where λ is the antenna resonance wavelength. By aligning the point of the frequency (= desired frequency) lower than the antenna resonance frequency (= frequency higher than the desired frequency) to the point where it is aligned with the LSI chip, it is matched with the LSI chip. The antenna length is preferably about 3 / 8λ to λ / 6. The antenna is preferably bent so as to wrap around inside. The inductance can be made as long as possible within a limited area by forming it in an empty space inside. The line width of the antenna may be partially increased to increase the area. It is also preferable to select an appropriate inductance length in consideration of the relative permittivity and thickness of the object to be attached. Moreover, you may remove partially the part with a low current density of an antenna part. The shape to be removed is preferably a slit shape. Further, it is desirable that the shape of the antenna portion after removal is a triangle or a quadrangular ring. An antenna is preferably formed on a sheet (paper, film, PET) with a metal mainly composed of Cu, Ag, and Al.
These are assumed to be used in the UHF band. (At 2.45 GHz, the meaning of downsizing will fade)
FIGS. 1-8 is a figure explaining the 1st Embodiment of this invention.

  As shown in FIG. 3, a dipole was formed with a size of 15 mm in length and 48 mm in width (effective total length: about 116 mm = 3 / 8λ) assuming a size of one quarter or less of the card size. The antenna of FIG. 3 has a dipole part 10 having a round shape. When an electromagnetic field simulation is performed with this antenna configuration, and the calculation results from f = 700 MHz to 3000 MHz are plotted on an admittance chart, a locus like a thin line in FIG. 1 (antenna without L) is drawn. The reason why the imaginary part = 0 is large because f = 1340 MHz because of downsizing, and Ra = 16Ω. In general, when a dipole is bent, the radiation resistance Ra becomes smaller than Ra = 72Ω of a normal dipole in a straight state. At this time, the point of f = 953 MHz is at the position indicated by the triangle shown as the L-less antenna in FIG. Therefore, by connecting the inductance part (S2 = 30 mm) 12 in parallel to this dipole as shown in FIG. 4, the locus is entirely rotated counterclockwise on the admittance chart. Then, the frequency characteristic draws a locus (antenna with L) as shown by a thick line in FIG. At this time, when an electromagnetic field simulation is performed, the point at f = 953 MHz becomes Ra = 8100Ω and La = 40 nH. Although this point is matched with respect to the imaginary part (inductance), the antenna radiation resistance Ra = 8100Ω is too large for the chip Rc = 1200Ω, so the reflection is usually too large and the antenna received power Think that almost bounces back into the air.

  However, when this antenna is actually made (copper is used to form a 35-micron-thick antenna) and the admittance is measured, the conductor has a loss. Therefore, as shown in FIG. It has been found that the position on the admittance chart goes inward considerably. At this time, it was found that measured Ra = 1300Ω and La = 40 nH. In other words, for La, it almost coincided with the value of the electromagnetic simulator, and Ra was empirically obtained to be a value close to Rc = 1200Ω of the chip. Thus, it can be seen that the small antenna and the chip are matched, and the antenna received power can be sufficiently supplied to the chip side.

  Here, since the antenna length (3 / 8λ) of the antenna of this embodiment is shorter than the λ / 2 long antenna with the best radiation efficiency, the radiation efficiency is slightly reduced, and the gain of the folded dipole with λ / 2 length = about For 2dBi, the gain of this antenna is about -2.7dBi as calculated by the electromagnetic simulator. As a result of actually fabricating both antennas and comparing the communication distances, a communication distance of 60% of the λ / 2 long folded dipole was obtained. However, it is extremely practically meaningful that a communication distance of 60% can be obtained for a small antenna of 48 mm × 15 mm.

  When the inductance length S2 is changed from S2 = 24 mm to 33 mm, as shown in FIG. 5, the La value is in good agreement with the simulation value and the measured value as shown in FIG. Regardless of S2, it became almost constant 1200Ω to 1300Ω. Further, as shown in FIG. 6, the gain value is about −3 to −2.5 dBi as a simulation value. Therefore, from these facts, when the Cc value varies depending on the type of chip, if the S2 value is appropriately selected according to the value, La matching with Cc is obtained, and furthermore, appropriate Ra is obtained, An antenna having a practical gain can be manufactured.

  To summarize the above, an inductance La is connected in parallel to a small antenna of λ / 2 wavelength or less, and the inductance length S2 is set to an appropriate length S2 so as to resonate according to the Cc value of the chip. On the other hand, the antenna radiation resistance Ra has a value close to the chip resistance Rc due to the conductor loss of the antenna and can be matched well with the chip. Judging from the results of electromagnetic field simulation alone, it is presumed that the antenna radiation resistance Ra is too large and does not match the chip, and this antenna design method is not usually conceivable, but from empirical data obtained from numerous prototype results, This manufacturing method was invented. Here, what is important in this manufacturing method is that the Rc of the chip is as large as 1000 to 2000Ω. Since the chip used for the RFID tag also extracts driving power from the received radiated electric field, the resistance Rc is set large in order to obtain the operating voltage of the chip. When the resistance Rc of the chip is small, it is considered that the antenna radiation resistance Ra does not have a value that matches the resistance Rc of the chip so that resonance occurs only by the conductor loss of the antenna.

  The dipole shape is not limited to the above, and dipole shapes as shown in FIGS. 8A and 8B are conceivable within a size of 15 mm in length and 48 mm in width. However, in these cases, the gains are −3.6 dBi and −3.0 dBi, respectively, and it can be seen that the gain of the antenna of FIG. 4 is slightly higher.

9-11 is a figure explaining the 2nd Embodiment of this invention.
In RFID, a tag antenna may be used by being attached to a target object. In that case, since the wavelength of the resonant wave changes depending on the relative permittivity (εr) of the attached object, it is necessary to select the optimum inductance length more strictly.

  As shown in FIG. 9A, a dipole is formed with a size of 10 mm in length and 60 mm in width (effective total length: about 75 mm = λ / 4), and electromagnetic field simulation and trial measurement are performed in the same way as in the first embodiment. Designed using For the antenna, it is assumed that the thickness of the attached object is t = 1 mm and the relative dielectric constant is εr = 1, 3, 5. (Air is εr = 1, plastic is εr = 3 to 4, rubber is εr = 4 to 5) As a result, the inductance La of the antenna has a value as shown in FIG. 10 with respect to the inductance length S2. Since it is known from the first embodiment that the actual measurement and the simulation value substantially coincide with each other, this simulation value is reliable. Also, from the antenna prototype results, the antenna radiation resistance was Ra = 1270Ω regardless of the S2 value. The gain simulation value is as shown in FIG. Here, the reason why the gain increases as εr increases is because the wavelength is shortened as εr increases, and the antenna length viewed from the shortened wavelength appears larger and approaches the λ / 2 length with good radiation efficiency. However, in this calculation, since the dielectric loss of the dielectric constant is assumed to be tan δ = 0.001, the dielectric loss hardly affects the antenna gain. Conversely, when the dielectric loss is large, the gain may decrease.

  From FIG. 10, the inductance value La of the antenna becomes 40 nH that matches the chip with Cc = 0.7 pF when the antenna is used alone, that is, when nothing is pasted, from the curve of εr = 1, S2 Select = 22mm. When pasting on an object with εr = 3 and thickness 1 mm, S2 = 20 mm, and when pasting on an object with εr = 5 and thickness 1 mm, S2 = 18 mm may be selected.

  Actually, an antenna was prototyped with S2 = 20 mm, and it was attached to a plastic product with a thickness of 1 mm, and the communication distance was measured. As a result, a communication distance of 65% of a λ / 2 long folded dipole was obtained. Although the communication distance is small, it can be said that the communication distance of 65% is extremely practical for a small antenna of 10 mm × 60 mm.

  In the present embodiment, it is assumed that the antenna is attached to one side of the antenna. For example, when the antenna is encased in resin, a dielectric is present on both sides of the antenna. If La value vs. S2 value data assuming that there are dielectrics on both sides of the antenna are saved, the antenna can be designed in the same way. Further, although the thickness is assumed to be 1 mm, even if the thickness is increased, the thickness may be calculated using an electromagnetic field simulator.

Further, the antenna shape used in this embodiment may be an antenna having the shape shown in FIGS. 4 and 8 as used in the first embodiment.
12-18 is a figure explaining the 3rd Embodiment of this invention.

  As shown in FIG. 12, assuming a half size of the card, a BowTie-shaped dipole (BowTie portion 13) is formed with a size of 37 mm in length and 48 mm in width (effective total length of about 110 mm = 3 / 8λ). The design was made using electromagnetic field simulation and prototype measurement with the same idea as the configuration. As a result, the La value as shown in FIG. 13 was obtained with respect to the inductance length S1. Since it is known from the first embodiment that the actual measurement and the simulation value substantially coincide with each other, this simulation value is reliable. Also, from the antenna prototype results, the antenna radiation resistance was Ra = 1150Ω regardless of the S1 value. Further, the gain simulation value is as shown in FIG. Since the area of the dipole portion is larger than that of the antenna shown in the first and second embodiments, the gain is higher than those.

From FIG. 13, in order to set La = 40 nH, S1 = 12.7 mm may be selected.
Actually, an antenna was prototyped with S1 = 12.7 mm, and the communication distance was measured. As a result, a communication distance of 75% of the λ / 2 long folded dipole was obtained. Although the communication distance is short, it can be said that the communication distance of 75% is extremely practical for a small antenna of 37 mm × 48 mm.

Here, when forming an antenna, there is a method of printing a conductive ink mixed with an Ag paste on a film or the like. In this case, if the amount of Ag paste is large, the cost per antenna increases. Therefore, as shown in FIG. 15, it is conceivable to form an antenna by hollowing out a part of the antenna where current does not flow so much. In FIG. 15, the BowTie portion 13 is cut out. In general, the high frequency current is concentrated on the edge portion of the conductor. Therefore, when the metal area is large, even if the metal near the center is removed, the antenna characteristics are not greatly affected. This is particularly effective in the case of such a BowTie-shaped antenna having a large metal area. When the La value and gain are obtained in the same manner as before, the results are as shown in FIGS. It can be seen that since the metal in the inductance portion is sufficiently left, the La value takes almost the same value as that of the antenna of FIG. 12 before being cut into a triangle. There is no problem because the gain value is only reduced by about 0.2 dB. By cutting this triangular shape, the metal area is reduced from 920 [mm ² ] to 540 [mm ² ], and the original antenna characteristics can be kept almost the same while greatly reducing the amount of conductive ink. it can.

  Actually, an antenna was prototyped with S2 = 12.5 mm, and the communication distance was measured. As a result, a communication distance of 70% of the λ / 2 long folded dipole was obtained. Although the communication distance is short, it can be said that the communication distance of 70% is extremely practical for a small antenna with a small metal area of 37 mm × 48 mm.

  In the present embodiment, the metal portion is cut out so as to form a triangular ring, but may be cut out into a slit shape as shown in FIG. In FIG. 18, instead of completely hollowing out the BowTie portion 13, a method of securing a gain by hollowing out in a slit shape is used.

  Further, the method of removing a portion where current is not concentrated is also effective for an antenna as shown in FIGS. 4 and 9A. Further, the method of removing a portion where the current is not concentrated is not limited to the antenna shape as shown in the embodiment, but is very effective.

  In the case of a manufacturing method in which conductive ink is printed on a film, an antenna is formed on a sheet (paper, film, PET) with a metal mainly composed of Cu, Ag, and Al. See US Pat. No. 6,259,408 for a detailed manufacturing method.

(Appendix 1)
In a tag antenna composed of a dipole antenna and a power feeding part on which a chip is mounted,
A dipole portion having a length shorter than a half of the antenna resonance wavelength;
A power feeding section provided in the center of the dipole section;
A tag antenna comprising: end portions provided with regions wider than the line width of the tie pole portion at both ends of the dipole portion.
(Appendix 2)
In a tag antenna composed of a dipole antenna and a power feeding part on which a chip is mounted,
A dipole portion having a length shorter than a half of the antenna resonance wavelength;
A power feeding section provided in the center of the dipole section;
An inductance part formed so as to surround the power feeding part and having both ends connected to the dipole part;
A tag antenna comprising: end portions provided with regions wider than the line width of the tie pole portion at both ends of the dipole portion.
(Appendix 3)
The Doug antenna according to any one of appendices 1 and 2, wherein both ends of the dipole portion are bent.
(Appendix 4)
The doug antenna according to any one of appendices 1 and 2, wherein both ends of the dipole portion are bent so as to approach each other.
(Appendix 5)
The duck antenna according to appendices 1 or 2, wherein the dipole portion is shaped like a butterfly wing.
(Appendix 6)
A tag antenna connected to a chip and supplying signal and power to the chip,
A dipole portion having a length shorter than a half of the antenna resonance wavelength;
In the dipole part, an inductance part having a length for adjusting the admittance of the tag antenna is provided so that the imaginary part of the admittance of the tag antenna has an absolute value equivalent to the imaginary part of the admittance of the chip.
A tag antenna, wherein a radiation resistance of the dipole part is made to be approximately equal to a resistance of the chip due to a loss of the dipole part.
(Appendix 7)
The tag antenna according to appendix 6, wherein the dipole portion is formed by being bent so as to wrap around inside.
(Appendix 8)
The tag antenna according to appendix 7, wherein the inductance part is formed in an empty space inside the dipole part.
(Appendix 9)
9. The tag antenna according to appendix 8, wherein a length of the dipole portion is longer than an inductance portion.
(Appendix 10)
7. The tag antenna according to appendix 6, wherein the length of the inductance part is determined according to a relative dielectric constant and a thickness of an object to which the tag antenna is attached.
(Appendix 11)
The tag antenna according to appendix 1, wherein a line width of the dipole portion is partially increased.
(Appendix 12)
The tag antenna according to appendix 11, wherein the dipole portion is formed such that a portion of the dipole portion having a low current density is partially cut out.
(Appendix 13)
13. The tag antenna according to appendix 12, wherein the dipole portion is cut out in a slit shape.
(Appendix 14)
The dipole part and the inductance part are formed by a method similar to printing using a liquid containing a metal mainly composed of copper, silver, or gold on a sheet of paper, film, or PET. The tag antenna according to Supplementary Note 1.

It is FIG. (1) explaining the 1st Embodiment of this invention. It is FIG. (2) explaining the 1st Embodiment of this invention. It is FIG. (3) explaining the 1st Embodiment of this invention. It is FIG. (4) explaining the 1st Embodiment of this invention. It is FIG. (5) explaining the 1st Embodiment of this invention. It is FIG. (6) explaining the 1st Embodiment of this invention. It is FIG. (7) explaining the 1st Embodiment of this invention. It is FIG. (8) explaining the 1st Embodiment of this invention. It is FIG. (1) explaining the 2nd Embodiment of this invention. It is FIG. (2) explaining the 2nd Embodiment of this invention. It is FIG. (3) explaining the 2nd Embodiment of this invention. It is FIG. (1) explaining the 3rd Embodiment of this invention. It is FIG. (2) explaining the 3rd Embodiment of this invention. It is FIG. (3) explaining the 3rd Embodiment of this invention. It is FIG. (4) explaining the 3rd Embodiment of this invention. It is FIG. (5) explaining the 3rd Embodiment of this invention. It is FIG. (6) explaining the 3rd Embodiment of this invention. It is FIG. (7) explaining the 3rd Embodiment of this invention. It is a figure explaining the tag antenna used for the conventional RFID system. It is a figure which shows the equivalent circuit of a RFID tag antenna. It is the figure which showed the example of an analysis by the admittance chart of the conventional tag antenna.

Explanation of symbols

10 Dipole part 11 Power feeding part 12 Inductance part 13 BowTie part

Claims (5)

In a tag antenna connected to a chip and supplying signal and power to the chip,
A dipole portion formed of a conductor and having an effective length of 1/6 to 3/8 of the antenna resonance wavelength at the maximum frequency in the operating frequency band;
A power feeding section provided in the center of the dipole section;
The tag antenna is formed so as to surround the feeding portion, and both ends thereof are connected to the dipole portion, and the imaginary part of the admittance of the tag antenna has an absolute value equivalent to the imaginary part of the admittance of the chip. of Chi lifting lengths for adjusting the admittance, and provided the inductance section which resonates with the capacitance component of the chip,
A tag antenna, wherein a radiation resistance of the dipole part is made to be approximately equal to a resistance of the chip due to a loss due to a conductor of the dipole part.   The tag antenna according to claim 1, wherein the dipole part is formed to be bent inward.   The tag antenna according to claim 2, wherein the inductance part is formed in an empty space inside the dipole part.   The tag antenna according to claim 3, wherein a length of the dipole portion is longer than that of the inductance portion.   The tag antenna according to claim 1, wherein the length of the inductance portion is determined according to a relative dielectric constant and a thickness of an object to which the tag antenna is attached.