Source: https://patents.google.com/patent/EP1850275A2/en
Timestamp: 2019-11-17 15:47:03
Document Index: 175172077

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EP1850275A2 - Tag-use antenna and tag using the same - Google Patents
EP1850275A2
EP1850275A2 EP06254316A EP06254316A EP1850275A2 EP 1850275 A2 EP1850275 A2 EP 1850275A2 EP 06254316 A EP06254316 A EP 06254316A EP 06254316 A EP06254316 A EP 06254316A EP 1850275 A2 EP1850275 A2 EP 1850275A2
EP06254316A
EP1850275A3 (en
EP1850275B1 (en
2006-08-17 Application filed by Fujitsu Ltd filed Critical Fujitsu Ltd
2007-10-31 Publication of EP1850275A2 publication Critical patent/EP1850275A2/en
2009-07-22 Publication of EP1850275A3 publication Critical patent/EP1850275A3/en
2018-12-05 Publication of EP1850275B1 publication Critical patent/EP1850275B1/en
239000000088 plastic resin Substances 0 abstract claims description 12
The present invention relates to an antenna (10) for an RFID tag allowing miniaturization while maintaining a relatively constant communication range. The antenna (10) has a feed part (8) of a folded dipole antenna (9) of a size of 53 mm long and 7 mm wide being connected to, and equipped with, an LSI chip of Rc= 500 ohms and Cc= 1.4 pF and is covered with plastic resin (13) of dielectric constant εr= 3 and thickness of t= 0.75 mm on both sides of the antenna. The dipole part of 1 mm wire path width of the antenna (10) is formed in a rectangular spiral by being folded inward into four bent portions (11-1, 11-2, 11-3, 11-4). The entire length of the dipole antenna (9) when unfolded is shorter than one half of a resonance wavelength of the antenna. An inductance part (12) is located between both dipole parts in the neighborhood of the center of the antenna. The inductance part (12) is connected to the chip location part (8) in parallel with both dipole parts.
The present invention relates to an ultra-miniature antenna ("tag-use antenna") used for a large-scale integration (LSI) chip and a tag employing the antenna in a radio frequency identification (RFID) system which is capable of carrying out communication between a reader/writer and a tag by using a radio high frequency signal.
An RFID system is for transmitting a signal of approximately one watt from a reader/writer (simply "RW" hereinafter), receiving the signal on a tag side and retransmitting a response signal back to the RW side, by using an ultra high frequency (UHF) between 860 MHz and 960 MHz, thereby enabling the RW to read information stored in the tag.
A communication range between the RW and tag is about 3 to 5 m, depending on the gain of the antenna, the operating voltage of the LSI chip, environmental conditions etc.
Figs. 1A, 1B and 1C are diagrams illustrating tag-use antennas used for a conventional RFID system. Fig. 1A shows an antenna comprising dipole parts 2 extending horizontally on both sides of a power feed part 1; Fig. 1B shows one having folded dipole parts 3 having both ends of the antenna of Fig. 1A turned back; and Fig. 1C shows one having an inductance part 4 connected in parallel with the dipole parts 2 to the feed part 1 shown in Fig. 1B.
Fig. 3 is a diagram exemplifying an analysis, by an admittance chart, of a tag using a conventional tag-use antenna. An admittance chart is indicated by zero ("0") ohm on the left side of a pure resistance line, which divides the circle of the chart into the top and bottom half, and infinite ("∞") ohms on the right side thereof.
As shown in Fig. 2, the antenna can be equivalently expressed by a parallel connection of an emission resistance Ra and of an inductance La, while an LSI chip can be equivalently expressed by a parallel connection of a resistor Rc and of a capacitance Cc.
Then, the parallel connection of the tag-use antenna and LSI chip makes the inductance La and capacitance Cc resonate, and they match at a desired resonance frequency f0 as is apparent from an expression "f0= 1/(2π√(LC))", resulting in power received by the tag-use antenna being adequately supplied to the LSI chip side.
That is, letting an emission resistance Ra of the tag-use antenna be 400 ohms for example, a resistance Rc of the LSI chip be 500 ohms, for example, a configuration be so as to cancel out resistance of both, and assuming L= La= 20 nano Henry (abbreviated as "nH" hereinafter) and C= Cc= 1.4 pF in the above noted expression of the resonance frequency, then a desired resonance frequency of f0= 953 MHz required for an RFID system is obtained.
For a basic antenna used for an RFID tag, the simplest conceivable is a dipole antenna of a whole length of about 145 mm which is constituted by dipole parts 2 extending horizontally in both directions of the feed part 1 shown by Fig. 1A.
In this configuration, the feed part 1 connected to the dipole parts 2 extracts power from a signal received in the dipole parts 2 and feeds the power to the LSI chip disposed on the feed part 1 and also transfers the signal per se to the LSI chip. The configuration of the dipole antenna actually measures an emission resistance Ra= 72 ohms.
Incidentally, impedance of an LSI chip of the above noted resistance Rc= 500 ohms and capacitance Cc= 1.4 pF is indicated at a position diagonally on the right below in the direction of about "-40 degrees" of an ωC zone in the admittance chart (Fig. 3 shows the position simply by a circular plot marked "chip").
In this case, an optimum position, in the admittance chart, of the dipole antenna resonating with the above described LSI chip is a position of the LSI chip symmetrically reversed relative to the pure resistance line of the admittance chart, and Fig.3 shows the position diagonally on the right above in the direction of about "+40 degrees" of an ωL zone.
This position is one for an impedance with an emission resistance Ra= 500 ohms and an inductance La= 20 nH (Fig. 3 shows the position by a circular plot marked "the most optimum position").
As such, an emission resistance Ra required for an RFID tag-use antenna corresponding to an LSI chip of resistance Rc= 500 ohms and capacitance Cc= 1.4 pF is very high, i.e., about 500 ohms, and therefore the emission resistance Ra= 72 ohms of the dipole antenna shown by Fig. 1A is far too small.
It is accordingly necessary to increase an emission resistance Ra up to about 500 ohms by devising a suitable configuration of the dipole antenna. One possibility is a folded dipole antenna having a folded dipole part 3 of a whole length of 145 mm folding back from the both ends of Fig. 1A, as shown by Fig. 1B.
This configuration makes it possible to increase the emission resistance Ra. This configuration is known to allow setting of emission resistance in the range of about 300 to 1500 ohms, depending on a wire width of the folded part.
Fig. 3 shows an impedance position of a folded dipole with an emission resistance Ra of 400 ohms indicated by a triangle on the pure resistance line.
Here, with the emission resistance Ra being maintained at 400 ohms, a further connection of an inductance part 4 to the feed part 1 of Fig. 1B in parallel with the dipole part 2 as shown in Fig. 1C rotates the antenna characteristic counter-clockwise on the admittance chart.
This results in positioning, close to the most optimized position, the antenna characteristic of the folded dipole antenna, connected with the inductance L, having a resonance frequency of 953 MHz as shown by a triangle as the folded dipole connected with the inductance L (the "L-connected folded dipole antenna" hereinafter) in the ωL zone of Fig. 3.
The admittance chart shown by Fig. 3 exemplifies the characteristic between 700 and 1200 MHz. In the range of the resonance frequency, it is apparent that the antenna characteristic locus 7 of the L-connected folded dipole antenna circles around the resonance most optimum value (i.e., the most optimized position of Ra= 500 ohm and La= 20 nH).
Incidentally, RFIDs are used by being attached to various bodies as a tag. In the case of such a body being made of styrofoam, the dielectric constant εr of the RFID is approximately 1.1 which is about the same as the value in air (εr= 1).
That is, in the case of attaching a tag onto styrofoam, it becomes about the same as when the tag is freely disposed in air.
In the case of attaching an RFID to a plastic body for example, an effective dielectric constant around the antenna becomes large if the thickness of the plastic is 2 mm, since the dielectric constant εr of a plastic material is about εr= 3.
Meanwhile, the behavior of the RW communicating with an RFID at the operating frequency 953 MHz is empirically known to be approximately the same as the characteristic at 953 MHz in the air displaced by 100 MHz.
As such, practicality is hampered if the communication range of the antenna fluctuates when being attached onto various kinds of bodies, that is, when the operating frequency is displaced, and therefore there is a need for an antenna whose range does not change even if it is attached to various kinds of bodies.
Therefore, a good antenna for an RFID is one capable of having a wide frequency band, that is, having a wide frequency characteristic.
The L-connected folded dipole antenna, shown by Fig. 1C, comprising the antenna characteristic as shown in Fig. 3 has an adequately wide band, e. g. , the bandwidth of the one rotation part 7a according to the antenna characteristic locus 7 of Fig. 3 is approximately 200 MHz, and can be characterized as a good antenna whose communication range is less affected by the material the tag is attached to (i.e., uninfluenced by a material to be attached to).
However, there is a strong demand by users for miniaturizing the RFID. An antenna with a size of 145 mm horizontal by 15 mm vertical is too large for tag use. It may be just possible to use it for managing a book for example, but there is no degree of freedom for using such an antenna in other applications, hence the need for further miniaturization.
Incidentally, if one tries to confine the entire size of an antenna to 80 by 20 mm for example, it is necessary to bend the antenna line in a serpentine fashion (or "meandering") in order to house the elongated line length into a small area.
That is, the miniaturization of an antenna narrows the frequency band. In other words, an RFID comprising such a miniaturized antenna has a range which varies drastically depending on the material it is attached to. This leads to practical problems in use of the RFID.
An antenna according to the present invention is one comprising a dipole antenna, a feed part and an inductance part, which are provided by a conductor in the same flat plane, wherein the feed part is provided at the center of the dipole antenna in a manner capable of receiving a chip, the inductance part is connected to the feed part in parallel with a dipole (dipole parts) of the dipole antenna, and the dipole antenna is formed in a rectangular spiral by being bent inward from both ends at bending parts which bend the dipole at least in four places respectively, with the entire length of each of the bending parts of the four places being shorter than one half of a resonance wavelength of the antenna when the bending parts are extended to a straight line.
The antenna is configured in such a manner that the inductance part is located in the neighborhood of the center of the dipole antenna and placed in the middle of the dipole, which is formed in the square spiral, of the dipole antenna. The tag-use antenna is configured in such a manner that the entire length of the antenna and the inductance part are adjusted so as to make an impedance of a tag at a reader/writer operation frequency of 953 MHz come close to the antenna's optimal value, for example. The conductor is either copper, silver or aluminum, for example.
The antenna is configured so that the feed part is connected to, and equipped with, a large scale integration (LSI) chip. The configuration may be so as to sandwich the tag-use antenna by a plastic resin or paper from both surfaces of the tag-use antenna. In this case the plastic resin is preferably an ethylene terephthalate film.
A tag embodying the present invention is configured to sandwich the tag-use antenna by plastic resin or paper from the both sides.
The present invention is contrived to enable a provision of an extremely compact, tag-use antenna whose communication range is little affected by a body on which the antenna is attached to, that is, the antenna maintaining a minimally changed communication distance, and provision of a tag using the tag-use antenna.
Fig. 4 gives a perspective view of a configuration of an extremely compact tag-use antenna according to an embodiment. Note that Fig. 4 shows a tag-use antenna along with a tag built in with the tag-use antenna. The tag is configured by sandwiching both sides of the tag-use antenna by a plastic resin or paper. Fig. 4 indicates a tag-use antenna internally by perspectively showing the plastic or paper tag.
The tag-use antenna 10 comprises a dipole antenna, a feed part and an inductance part which are formed by a conductor within the same plane. The conductor preferably uses copper, silver and/or aluminum.
The feed part is formed to enable siting of an LSI chip at the center of the dipole antenna and comprises a chip equipment part 8 as shown in Fig.4. With the chip equipment part 8 being at the center, either side comprises a dipole part 9 of a line path width of 1 mm, thereby configuring a dipole antenna as a whole.
The dipole antenna constituted by the dipole parts 9 on both sides is formed in a rectangular spiral by successively folding the dipoles inward at right angles at bending parts 11 (i.e., 11-1, 11-2, 11-3 and 11-4) in at least four places. That is, the present embodiment has four bending parts (bent portions) on each side.
The entire length of the dipole antenna is made shorter than one half of a resonance wavelength of the antenna, as described later in detail, when the respective bending parts are extended in straight lines.
In the neighborhood of the dipole antenna is provided an inductance part 12 intermediate between both dipole parts 9 which are respectively formed in the above described rectangular spirals. The inductance part 12 is connected to the chip equipment part 8, that is, the feed part of the antenna, in parallel with both dipole parts 9.
The dipole antenna (i.e., the tag-use antenna 10) is comprised as a tag by connecting, and fixing, an LSI chip of Rc= 500 ohms and Cc= 1.4 pF, to and with the feed part (i.e., the chip equipment part 8), and the both surfaces (i.e., the top and bottom surfaces in the view of Fig. 4) are covered by plastic resin 13 of the dielectric constant εr= 3 and thickness t= 0.75 mm.
The plastic resin 13 uses an ethylene terephthalate film, for example. Or, a suitable paper may be used for covering the both surfaces in place of the plastic resin 13.
The antenna characteristic locus 14 revolves around the most optimum value of the antenna, with the locus 14 being the closest thereto in the neighborhood of 953 to 1000 MHz of the RW operation frequency which is indicated as the area enclosed by the dotted line ellipse 15 in Fig. 5. That is, a reflectance between the LSI chip and dipole antenna is small.
Further increasing the frequency so as to approach a position exceeding 1050 MHz indicated by a dotted line ellipse 16 in Fig. 5, the reflectance between the LSI chip and dipole antenna becomes large because it is far from the most optimum value of the antenna.
Fig. 6 is a diagram showing a frequency characteristic of a reflection S11 of the tag-use antenna 10 calculated by the above noted electromagnetic field simulator, showing frequencies (800 MHz through 1100 MHz) on the horizontal axis and reflections S11 (-5 dB to 0 dB) on the vertical axis. As understood from Fig. 6, the reflection S11 indicates a minimum at around 975 MHz.
Fig. 7 is a diagram showing a calculation value of an antenna gain of the tag-use antenna 10 calculated by the above noted electromagnetic field simulator, showing frequencies (800 MHz through 1100 MHz) on the horizontal axis and antenna gains (-4 dBi through 2 dBi) on the vertical axis. The antenna gain shown in Fig. 7 indicates a maximum at around 1050 MHz.
Fig. 8 is a communication distance characteristic chart which can be obtained by combining the above noted reflectance characteristic and a gain characteristic of a tag-use antenna in an Excel chart, showing frequencies (800 MHz through 1100 MHz) on the horizontal axis and relative communication distances specified by a maximum distance (range) on the vertical chart.
As described above, a communication distance characteristic possessed by the tag-use antenna 10 is asymmetrical in the left and right directions relative to the RW operation frequency of 953 MHz, with the gain changing gradually on the higher frequency side of the RW operation frequency of 953 MHz and a characteristic of a relatively stable communication distance.
The above noted calculation by the electromagnetic field simulator specifies the top and bottom of the plastic resin 13 shown in Fig. 4 as the air and therefore the communication distance at the RW operation frequency of 953 MHz is a distance when the tag-use antenna is in the air. The communication distance in the air is a distance of 0.95 as opposed to the specified maximum distance as shown in Fig. 8. That is, 95% of the maximum distance is secured.
When attaching the tag-use antenna 10 to plastic of εr= 3 and 2 mm thick, an effective dielectric constant around the antenna becomes large, down-shifting a band approximately by 10%. That is, the waveform shown in Fig. 8 shifts toward the lower frequency side by approximately 100 MHz.
In other words, the value of the relative communication distance at 1050 MHz, which is higher than 953 MHz by about 10%, becomes a communication distance when attaching the tag-use antenna onto a 2 mm thick plastic body according to the waveform shown in Fig. 8. The communication distance in this case is a distance of 0.8 as opposed to the specified maximum distance as shown in Fig. 8, securing 80% of the maximum distance.
As is also apparent from Fig. 8, the antenna 10 according to the present embodiment is configured to ensure 80% of the maximum communication range in air, when being attached to styrofoam or to 2 mm plastic, and hence possesses a stable communication range independent of the body it is attached to.
A remarkable characteristic of the tag-use antenna according to the present embodiment is that the antenna pattern constituted by the dipole part and inductance part is adjusted in a manner to approach the most optimum value of the antenna in the neighborhood of the RW operation frequency of 953 MHz, while reflectance becomes large, departing from the most optimum value in higher frequencies than 953 MHz, which is compensated by higher antenna gain, resulting in keeping the communication distance at a minimal loss.
In order to obtain higher antenna gains at higher frequencies than 953 MHz, the entire length of the antenna is configured to be close to one half of the antenna resonance wavelength providing good gain efficiency.
The antenna pattern of the tag-use antenna 10 according to the present embodiment is configured in such a manner that the entire length of the antenna is a little shorter than one half of the antenna resonance wavelength λ when the bending parts (bent portions) 11 are unfolded.
The example shown by Fig. 4 is configured such that the entire length of the antenna is approximately 120 mm when unfolded, while one-half of the antenna resonance wavelength λ is approximately 130 to 140 mm, with the 10 mm tolerance band of the antenna resonance wavelength λ comprehending the plastic resin 13 on the top and bottom sides.
Meanwhile, the dipole part is maintained as straight as possible by bending from the (out-)side to inside, and the inductance part is desirably provided between both dipole parts because they must not approach each other.
This configuration enables an accomplishment of a tag-use antenna possessing an extremely high distance stability, ensuring at least 80% of the maximum communication distance whether in air, or when attached to styrofoam or 2 mm thick plastic.
While four bending parts are formed on each of the dipole parts for the size of 53 mm horizontal by 7 mm vertical as shown in Fig. 4, the number of folds can be increased to five or six, and so on, as the antenna becomes smaller.
A tag-use antenna (10) comprising a dipole antenna (9) having two dipole parts, a feed part (8) and an inductance part (12) which are formed by a conductor in the same flat plane, wherein
the feed part (8) is provided at the center of the dipole antenna (9) in a manner capable of receiving a chip,
the inductance part (12) is connected to the feed part (8) in parallel with the dipole parts of the dipole antenna (9), and
each dipole part is formed in a rectangular spiral by being bent inward from both ends into bent portions (11-1, 11-2, 11-3, 11-4) which bend the dipole part at least in four places respectively, with the entire length of the bent portions (11-1, 11-2, 11-3, 11-4) being shorter than one half of a resonance wavelength of the antenna when the bent portions (11-1, 11-2, 11-3, 11-4) are extended in a straight line.
The tag-use antenna (10) according to claim 1, wherein
said inductance part (12) is provided in the neighborhood of the center of said dipole antenna (9) and placed between the two dipole parts of the dipole antenna (9).
The tag-use antenna (10) according to claim 1 or 2, wherein
the entire length of the antenna and said inductance part (12) are adjusted so as to make an impedance of a tag at a reader/writer operation frequency of 953 MHz come close to the antenna's most optimum value.
The tag-use antenna (10) according to claim 1, 2, or 3, wherein
said conductor comprises copper, silver or aluminum.
The tag-use antenna (10) according to claim 1, 2, 3, or 4, wherein
said feed part (8) is connected to, and equipped with, a large scale integration (LSI) chip.
A tag sandwiching the tag-use antenna (10) according to any preceding claim by a plastic resin (13) or paper from both surface of the tag-use antenna (10).
The tag according to claim 6, wherein
said plastic resin (13) is an ethylene terephthalate film.
EP06254316.0A 2006-04-26 2006-08-17 Tag-use antenna and tag using the same Active EP1850275B1 (en)
EP1850275A2 true EP1850275A2 (en) 2007-10-31
EP1850275A3 EP1850275A3 (en) 2009-07-22
EP1850275B1 EP1850275B1 (en) 2018-12-05
EP06254316.0A Active EP1850275B1 (en) 2006-04-26 2006-08-17 Tag-use antenna and tag using the same
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