JP2001156526A - Antenna forming method for non-contact type data transmission and reception body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the efficiency of transmission of power and data transmission that is conducted through electromagnetic induction by changing stray capacitance generated between a coil section and a bridge section of an antenna, thereby conducting tuning, and suppressing reduction in the transmission efficiency of power and data transmission. SOLUTION: In forming an antenna 5 of a noncontact data transmission/ reception body 4 that consists of the coil pattern shaped antenna 5 having a bridge section 12 bridging partly over a coil section 10 and of an IC chip 13 mounted on the antenna, adjusting the stray capacitance formed between the bridge section 12 and the coil section 10 changes the resonance frequency into a prescribed frequency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for forming an antenna of a non-contact data transmitter / receiver.

[0002]

Conventionally, an information recording medium (R) such as a non-contact type IC tag capable of recording and erasing data by transmitting and receiving data in a non-contact state.
F-ID (RadioFrequency IDent)
Non-contact type data transmitter / receiver used for the purpose of application) is configured by disposing a coil pattern antenna having a bridge part on a film or sheet base and mounting an IC chip on the antenna. have. The antenna is formed by a printing method suitable for mass production, and the antenna is formed by printing conductive ink on a base material in a coil pattern.

[0003] Data transmission to and reception of data from and to the non-contact data transmitter / receiver having the above-described structure is performed between a reader / writer unit of another device. -Data is exchanged between the writer unit and the writer unit when the writer unit comes closer to the required communication distance. FIG. 1 schematically shows power supply and data transfer between a non-contact type data transceiver and a reader / writer unit, and an electromagnetic field generated on the antenna 2 side of the reader / writer unit 1. 3, the antenna 5 of the non-contact type data transmitting / receiving body 4 enters,
Due to the electromagnetic induction generated by the antenna 5, power is transmitted 6 from the reader / writer unit 1 to the non-contact data transmitter / receiver 4 in a non-contact manner. In addition, the non-contact type data transmitter / receiver 4 is operated by the power to perform data transmission / reception 7.

As described above, since both power transmission and data transmission are performed by electromagnetic induction between the antenna between the reader / writer unit and the non-contact type data transmitter / receiver, non-contact transmission is required to improve transmission efficiency. It is necessary to configure a tuning circuit that tunes to input / output by the reader / writer unit in the circuit configuration on the side of the type data transmitting / receiving body. On the other hand, as shown in FIG. 2, the circuit configuration of the antenna 5 is such that a coil C '(a capacitance C) is added to a coil L' (an inductance L component).
Component A) can be represented by a type A or type B parallel resonance circuit in which the components are connected in parallel. That is, the antenna 5 is an equivalent circuit to these. Then, as shown in Expression 1, the coil L '
By changing the values of (inductance L) and capacitor C '(capacitance C), the resonance frequency f can be changed. R is a resistance. Therefore, from the viewpoint of the circuit expressing the antenna 5, it is possible to configure the above-described tuning circuit in this antenna. A conventional example in which a tuning circuit is changed without using a chip capacitor is disclosed in Japanese Patent Application Laid-Open No. 8-180160. Japanese Patent Application Laid-Open Nos. 8-216570 and 8-3
No. 16411 and the like.

[0005]

(Equation 1)

[0006]

In order to obtain a coil-shaped antenna of a non-contact type data transmitter / receiver, as shown in FIGS. 3 and 4, a conductive paste 8 (for example, silver paste) or the like is made of PET or the like. A coil portion 10 is formed by printing on a base material 9 such as paper, and an insulating paste 11 is formed thereon.
Is printed, and the bridge section 12 is further printed thereon. After that, the IC chip 13 is mounted. Although the antenna of the non-contact type data transmitter / receiver is formed as described above, it is actually rare that the antenna of the same pattern is continuously manufactured for a long time, and the size of the antenna is changed according to various requirements. There are things you need to do.
Specifically, it is discussed in the international standard ISO15693 (defined in ISO14443).
Even in the case of the non-contact type data transmitter / receiver 4 which is a near-type (proximity-type) card-shaped tag using 56 MHz, the antenna 5 may be formed on the entire surface of the card-size base material as shown in FIG. For example, an antenna may be formed on a half-sized base material surface as shown in FIG. 5 or may be formed near one side of the base material surface for convenience in printing after forming the tag. There is also.

[0007] Then, the antenna 5 having a card-size substrate surface as shown in FIG. 3 and having a number of turns of, for example, 6 or 7 turns, is reduced to a half size without changing the number of turns or line width. If formed, the inductance L changes. Therefore, as shown in FIG. 3, the inductance L obtained by the antenna 5 having the number of turns of, for example, 6 or 7 turns over the entire surface of the substrate is obtained by the antenna 5 having a half size of the substrate surface as shown in FIG. 5. In that case, for example, 8, 9 turns are required. Thus, in order to obtain the same inductance L and sharpness Q while changing the size of the antenna, it is necessary to change the number of turns and the line width of the antenna.

However, if the number of turns or the line width of the antenna is changed, the resonance frequency changes, making it difficult to tune the antenna. Further, when the capacitance C _{chip of} the IC chip is different for each chip, there is a problem that the resonance point is shifted. For this reason, when an antenna is formed by printing using a conductive paste, when power and data are transmitted by electromagnetic induction between the read / write unit and the non-contact type data transmitter / receiver, the read / write There is a disadvantage that power is not synchronized between the unit and the non-contact type data transmitter / receiver, and the transmission efficiency of power and data transmission is reduced.

As a result of diligent studies on the above-mentioned disadvantages, the present inventors have noticed the following points. That is, in the non-contact data transmitter / receiver, since the antenna formed using the conductive paste has a structure in which a part is crossed to the coil part as a bridge part as described above, the capacitance C is the distribution capacitance of the antenna. C _L and the stray capacitance (capacitor) C generated between the coil portion and the bridge portion of the antenna
Generated by a _B, and the number of turns and the line width is changed, changes the stray capacitance C _B generated between the coil portion and the bridge portion straddling this antenna is intended by noting the capacitance C is changed, also , The distributed capacitance C _{L of the} antenna,
A floating capacitance C _B generated between the coil portion and the bridge portion, I
Among the C chip capacitance C _Chip, generally most variation in the greater when the number of turns and the line width is changed is defined by noting the a stray capacitance C _B. The present invention has been made in view of the above circumstances, and possible to tune an object by changing the floating capacitance C _B generated between the coil portion and the bridge portion of the antenna, when performing power, data transmission by electromagnetic induction, power, It is an object of the present invention to improve transmission efficiency by suppressing a decrease in transmission efficiency of data transmission.

[0010]

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above problems, and has been made in consideration of the above circumstances. In forming the antenna of the contact-type data transmitting / receiving body, the resonance frequency is changed to a predetermined value by adjusting a stray capacitance formed between the bridge portion and the coil portion. An object of the present invention is to solve the above-mentioned problem by providing a method of forming a body antenna.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described in detail based on embodiments. Note that although the embodiment mode describes a case in which an antenna is formed using a conductive paste, the present invention is not limited thereto, and the present invention can be applied to formation of an antenna by etching or the like. A first embodiment of the present invention will be described. In some cases, the inductance L and the resonance frequency f of the antenna of the non-contact data transceiver to be formed are specified in advance. Then, it is considered the capacitance C as the equivalent to the floating capacitance C _B. This is because, as described above, on the grounds that the variation in the stray capacitance C _B is the largest when the number of turns and the line width is changed. Accordingly, the stray capacitance C _B to be obtained as a capacitance C in the formula 1 is calculated from Equation 1 the capacitance C. Then, the capacitance C is applied to the following equation 2 for calculating the capacitance between the parallel plate electrodes, and the area where the coil section 10 and the bridge section 12 of the antenna 5 intersect is obtained. Next, the line width of the bridge section 12 is calculated by the following equation 3, and if the line width is determined, the bridge section 12 is calculated using the line width.
Is formed by printing using the conductive paste 8. Thereby, the stray capacitance formed between the bridge portion and the coil portion is adjusted, and the resonance frequency is changed to be equal to a predetermined value (for example, the resonance frequency on the read / write unit side) to tune the antenna. Can be formed.

The following equation (2) for calculating the capacitance between the parallel plate electrodes is a formula for determining the capacitance of a normal capacitor, and the parallel plate electrode indicates the parallel plate electrode in the capacitor. . Then, when this equation 2 is used, the capacitance C obtained from the above equation 1 (≒ floating capacitance C _B ) is applied to the capacitance of the equation 2, and the dielectric constant is determined when the bridge portion is formed. The dielectric constant of the insulating paste to be used is applied. The distance between the parallel plate and the coil portion, that is, the thickness of the insulating paste is applied. Then, the parallel plate area in Equation 2 is the area where the coil section and the bridge section intersect. From the area, if the number of turns of the coil section and the line width of the coil section in Equation 3 are determined, The line width of the bridge is calculated.

[0013]

## EQU2 ## Capacitance = dielectric constant (ε) × parallel plate area / parallel plate distance (2)

[0014]

## EQU00003 ## Line width of bridge portion = (d.times.C) / ((number of windings of coil portion.times.wire width of coil portion) .times..epsilon.). Capacitance d: distance between coil portion and bridge portion (that is, thickness of insulating paste) ε: dielectric constant (dielectric constant of insulating paste)

A second embodiment will be described. In the second embodiment, the line width of the bridge portion is printed wider and the IC is printed.
After mounting the chip, it is measured with an impedance analyzer or the like.
In order to cut the distance, the bridge part is cut with a laser processing machine or the like to reduce the line width. Thereby, the stray capacitance formed between the bridge portion and the coil portion is adjusted, and the resonance frequency is changed to be equal to a predetermined value (for example, the resonance frequency on the read / write unit side) to tune the antenna. Can be formed. This method is effective when the capacitance C _chip of the IC chip varies.

A third embodiment will be described. In this embodiment, for example, the shape of the antenna 5 shown in FIG.
When the size of the antenna 5 is reduced and the number of turns and the line width of the antenna 5 are changed as shown in FIG. 6, the cross-sectional area between the coil unit 10 and the bridge unit 12 (indicated by a virtual line in FIG. 6). Is approximately equal to the cross-sectional area of the antenna when the antenna shape is large.
The line width of the coil portion 10 is changed only at the portion where the bridge portion 12 straddles at 0. Thus, even if the shape of the entire antenna changes, it is easy to reduce the change in the capacitance C as the antenna, and adjust the stray capacitance formed between the bridge and the coil to reduce the resonance frequency. An antenna that is tuned by changing it to match a predetermined value (for example, the resonance frequency on the read / write unit side) can be formed.

[0017]

According to the present invention described above, the resonance frequency can be changed only by changing the line width of the bridge portion of the antenna and the coil width over which the bridge portion extends, and the read / write operation can be performed. It is easy to match the resonance frequency of the unit side, and the power and data transmission between the read / write unit and the non-contact type data transmitter / receiver can be improved, and the basic characteristics of the non-contact type data transmitter / receiver The effect is that the communication distance can be increased.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram schematically showing power supply and data transfer between a non-contact type data transceiver and a reader / writer unit.

FIG. 2 is an explanatory diagram showing an equivalent circuit of an antenna of a non-contact type data transmitting / receiving body.

FIG. 3 is an explanatory view showing an antenna arranged on a base material of a non-contact type data transmitting / receiving body.

FIG. 4 is an explanatory diagram showing a cross section of an antenna similarly arranged on a base material passing through a bridge portion.

FIG. 5 is an explanatory diagram showing an antenna having a reduced shape.

FIG. 6 is an explanatory diagram showing an antenna in which a line width of a coil portion straddled by a bridge portion is reduced.

[Explanation of symbols]

 4: Non-contact data transmitter / receiver 5: Antenna 10: Coil unit 12: Bridge unit

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (reference) H01Q 1/38 G06K 19/00 K // H04B 5/02 HF term (reference) 2C005 MA40 MB10 NA08 5B035 AA00 BA01 BB09 CA08 CA11 CA23 5J046 AA03 AB11 PA07 5K012 AB03 AC06 AC08 AC10 AD00 AE13 BA02

Claims (1)

[Claims] 1. A non-contact type data transmitter / receiver comprising a coil-patterned antenna having a bridge portion partially extending over a coil portion and an IC chip mounted on the antenna. A method for forming an antenna for a non-contact type data transmitter / receiver, comprising: adjusting a stray capacitance formed between the antenna and a unit to change a resonance frequency to a predetermined value.