JP2006202174A - Contactless data carrier and manufacturing method of same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a contactless data carrier, such as a contactless IC card or IC tag, that comprises an antenna enabling a high degree of freedom in designing a built-in resonance circuit and an easy adjustment of resonance frequency, and a manufacturing method thereof. <P>SOLUTION: An antenna coil 2 is formed in a linear or planar pattern, and the pattern is extended to form an inductor 4 by the same pattern forming method, so that the antenna coil 2 and the inductor 4 are connected in series. With the number of turns and winding pitch of the antenna coil 2 unchanged, a resonance frequency and a Q value can be adjusted. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a so-called non-contact data carrier that reads / writes data in a non-contact manner, such as a non-contact IC card used as an ID card or a commuter pass, or an IC tag used in logistics management. It relates to an antenna of a contact data carrier.

  In recent years, records called contactless data carriers such as contactless IC cards and IC tags that exchange data without contact with external reader / writer devices such as security management of personal data, distribution and distribution management of people, and ticket gates for transportation systems. The media is spreading. Conventionally, this type of non-contact data carrier has an IC chip and an antenna as a basic configuration, and a resonance circuit is formed by an inductance component of the antenna and a capacitance component inside the IC chip. In order to maintain good communication between the non-contact data carrier and the reader / writer, it is desirable to match the resonance frequencies of both. However, in practice, there are variations in the inductance component and capacitance component of the resonance circuit of the non-contact data carrier. Therefore, in order to obtain a desired resonance frequency, it is necessary to adjust either or both of the inductance component and the capacitance component of the non-contact data carrier.

  In general, when adjusting this resonant circuit, the number of turns of the antenna pattern or the winding interval is changed to adjust the inductance component, or when the required capacitance cannot be obtained only by the IC chip, Either or both methods of adjusting the capacitance component by adding a separate capacitor in parallel are tried.

  FIG. 5 is an explanatory diagram of a conventional non-contact data carrier. A circuit configuration including an IC chip 3 and an antenna 2 of a conventional non-contact data carrier 1 is schematically shown on a card-like substrate 5. The antenna 2 is formed in a loop shape by circling along the outer periphery of the base 5, and the IC chip 3 is connected to both ends of the antenna 2. The antenna 2 includes a winding made of a coated copper wire, a pattern coil formed by etching a vapor-deposited conductor, a printed pattern coil using a conductor paste, or the like. A chip capacitor or a capacitor 6 formed of a parallel plate capacitor pattern formed by etching / printing is connected in parallel to adjust the capacitance component of the circuit. Alternatively, a desired resonance frequency is obtained by adjusting the inductance component by changing the setting conditions of the number of windings or coil patterns constituting the antenna 2 and the winding interval.

  Furthermore, setting the figure of merit Q in the resonant circuit to an appropriate value is also an important factor for good communication. When the internal resistance of the resonance circuit is small, the Q value is high. When this Q value is high, good communication can be maintained when the resonance frequency on the non-contact data carrier side and the reader / writer side match, but conversely, if the resonance frequency slightly shifts, a good communication state is obtained. Not secured. That is, when the Q value is high, the sharpness of the circuit becomes high, and the frequency matching range necessary for obtaining a predetermined communication quality becomes narrow. Therefore, in order to obtain a desired Q value, it is necessary to design a circuit in which a resistance component is added in addition to the inductance component and capacitance component of the resonance circuit described above.

  One example of these techniques is described in Patent Document 1. This relates to a method for adjusting the antenna characteristics of a non-contact type IC card. The card base has a resonance circuit including an antenna coil, a planar adjustment resistor, and an adjustment capacitor. The Q value of the resonance circuit is adjusted by adjusting, and the resonance frequency is adjusted by adjusting the capacitance of the adjusting capacitor to ensure a good communication state.

JP 2001-10264 A

  However, when adjusting the resonance frequency by changing the number of turns of the antenna and the winding interval, it is necessary to start designing from the antenna shape itself, so a considerable amount of time is required for the design including the antenna shape itself. The design conditions such as the above are constrained and the degree of design freedom is reduced. That is, it has been virtually impossible to adjust only the inductance component of the circuit without changing the antenna shape. Further, when the resonance frequency is adjusted by connecting capacitors in parallel, there is a restriction on the thickness dimension of the capacitor to be used because there is a limitation on the shape dimension of the non-contact data carrier, particularly in the thickness direction. For this reason, when a commercially available chip capacitor or the like is used, the selection range is narrowed, and the degree of freedom in design is reduced. At the same time, when a parallel capacitor is used, the Q value of the resonance circuit tends to be too high, and the resonance frequency matching range for maintaining good communication is narrowed. Further, in the adjustment method described in the above-mentioned Patent Document 1, since a resistance pattern and a capacitor pattern circuit are formed on a substrate, and a part of the trimming process is performed to remove and cut, the man-hour is increased. There was a problem that the performance was not improved.

  Therefore, the present invention makes it possible to easily adjust the inductance component of a resonance circuit having an IC chip and an antenna as a basic configuration, and thereby to provide a non-contact data carrier including an antenna capable of obtaining a desired resonance frequency, and It is in providing the manufacturing method. This also improves the degree of freedom in circuit design.

  In order to solve the above-described problems, the present invention provides a non-contact data carrier that includes an IC chip and an antenna, and includes a resonance circuit that resonates at a specific frequency, wherein an inductor is connected in series to the main body of the antenna. It is a non-contact data carrier that is characterized.

  According to another aspect of the present invention, there is provided a non-contact data carrier manufacturing method including an IC chip and an antenna, and a resonance circuit that resonates at a specific frequency, wherein the antenna body is formed in a linear or planar pattern, and A non-contact data carrier manufacturing method characterized in that the pattern is extended to form an inductor by a pattern forming method similar to that of the main body of the antenna.

  According to the present invention, it is possible to adjust the resonance frequency of the resonance circuit without changing the number of turns and the winding interval of the antenna body by providing the inductor in series with the antenna body. That is, the resonance circuit condition can be changed by controlling the inductance value of the inductor connected to the antenna body. At the same time, it is possible to adjust or fix the Q value of the circuit to a desired value. In addition, since the inductor is formed by the same formation method as that for the antenna pattern, the circuit pattern can be easily formed regardless of the restriction in the thickness direction. Therefore, it is possible to provide a contactless data carrier having an antenna with a high degree of freedom in circuit design.

  Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is an explanatory diagram of a non-contact data carrier showing an example of the present invention. A planar arrangement of the main body 2 of the IC chip 3 antenna and the inductor 4 on the card-like base 5 is schematically shown. The non-contact data carrier 1 includes a base 5 made of a resin sheet such as polyethylene terephthalate (PET), PET-G, or polyvinyl chloride (PVC), an antenna body 2, a planar inductor 4, and an IC chip 3. First, when designing the antenna main body 2, the size (area, length, etc.) of the antenna for transmitting and receiving information via an electric field or magnetic field, and the antenna main body (antenna coil) 2 in advance. In consideration of inductance, stray capacitance, and internal resistance, the number of turns, winding interval, conductor width, etc. are set and this condition is fixed. At the same time, various conditions of the planar inductor 4 that satisfy the resonance conditions including the capacitance component of the IC chip 3 necessary for obtaining a desired resonance frequency are determined. Under this condition, the antenna coil 2 is formed by arranging a pattern coil formed by etching a winding made of a coated copper wire or the like and a vapor-deposited conductor on the substrate 5 made of a resin sheet, or a printed pattern coil made of a conductive paste. . One end of the spiral planar inductor 4 is connected to one end of the antenna coil 2. The planar inductor 4 is formed on the substrate 5 at the same time as the antenna coil 2 is formed. In practice, one end of the antenna coil 2 and one end of the planar inductor 4 are continuous. The planar inductor 4 is formed by extending the antenna coil 2. One terminal of the IC chip 3 is connected to the other end of the planar inductor 4, and the other terminal of the IC chip 3 is connected to the other end of the antenna coil 2. Configure a series circuit.

  In general, the IC chip 3 has a capacitance component of around 40 pF. Further, the antenna coil 2 has its own stray capacitance, and the substrate 5 itself has a small capacitance component. Further, the antenna coil 2 has a specific inductance component, and the planar inductor 4 also has a specific inductance component. Among these, the capacitance components of the IC chip 3, the antenna coil 2 and the base 5 and the inductance component of the antenna coil 2 are known and determined as described above. In order to obtain a desired resonance frequency, it is necessary to adjust a resonance circuit constituted by these capacitance component and inductance component. In this case, as described above, since the capacitance component of the IC chip 3, the antenna coil 2 and the substrate 5, and the inductance component of the antenna coil 2 are determined, the resonance frequency is a plane additionally connected in series to the antenna coil 2. It can be adjusted by controlling only the inductance value of the inductor 4, that is, by controlling the resonance condition by changing the number of turns of the inductor 4, the winding interval, the winding shape, and the like. However, stray capacitance from the inductor 4 itself is also generated at this time, but it is very small compared with the capacitance of the IC chip 3 and may be ignored if it is not a strict design.

In general, the resonant frequency f _c is given by Equation (1) the capacitance component of the resonance circuit C, and when the inductance component was L.
f _c = 1 / (2π · (L · C) ^1/2 ) (1)

In Equation (1), C represents the capacitance component of the entire resonance circuit, and L also represents the entire inductance component. However, for the sake of easy understanding, C is the capacitance component of the IC chip 3, and L is It is assumed that the inductance component of the inductor 4 and the inductance component of the antenna coil 2 are fixed. In this case, the value is assumed to be zero, and other parasitic components are also ignored. Here, the inductance value of the inductor 4 when the desired resonance frequency is 13.56 MHz and the capacitance component C of the IC chip 3 is 40 pF is calculated. From equation (1), the inductance value of inductor 4 to be connected to antenna coil 2 is given by equation (2).
L = 1 / ((2π · fc) ² · C) (2)

  When calculating by substituting fc = 13.56 MHz and C = 40 pF into the equation (2), L≈3.4 μH. Therefore, a desired resonance frequency can be obtained by designing the inductor 4 that matches this inductance value and connecting it in series to the antenna coil 2. In this way, the resonance condition can be changed by adjusting only the inductance value of the inductor 4 connected to the antenna coil 2 while fixing the number of turns of the antenna coil 2 or the winding interval condition. However, in the actual design, it is necessary to adjust in consideration of the parasitic component such as the stray capacitance described above, the inductance component of the antenna coil 2, and the like.

Further, as described above, when this is regarded as a series resonance circuit, generally, the Q value that is the sharpness of the series resonance circuit is given by Expression (3).
Q = (ω _c · L) / R (3)

Here, R represents the internal resistance of the resonant circuit, L is an inductance component, ω _c = 2πf _c. Here again, as in the previous case, when L is only the inductance component of the inductor 4 and the calculation is performed by ignoring the inductance component of the antenna coil 2, R is almost determined in the equation (3). As the L value increases or decreases, the Q value varies. Therefore, a desired Q value can be set only by changing the condition of the inductor 4 connected to the antenna 2 while the winding condition of the antenna 2 is fixed, and intentionally in order to widen the allowable range of the response frequency. It is also possible to lower the Q value. The rough design is in time for this calculation, but in the actual design, it is necessary to adjust the internal resistance of the inductor 4 to be connected.

  The antenna coil 2 and the inductor 4 connected to the antenna coil 2 can be manufactured by basically the same material and the same formation method. Specifically, a predetermined antenna pattern and an inductor pattern formed by extending the antenna pattern are set, and the conductor film formed by sputtering or vapor deposition on the substrate 5 is left by etching and leaving these patterns. There is a method of forming, or a method of forming a mask pattern of a predetermined antenna coil 2 and inductor 4 on the same screen and screen-printing with a conductive paste. According to these methods, the antenna coil 2 and the inductor 4 can be formed at the same time, and by simultaneously forming a pattern by the same method, it is possible to easily manufacture without increasing the man-hours, thereby improving productivity. Is expected.

  2 to 4 are explanatory diagrams of a non-contact data carrier showing another example of the present invention. The inductor 4 connected to the antenna coil 2 has a rectangular spiral shape as shown in FIG. 2 in addition to the rectangular spiral inductor 4 shown in FIG. 1, and a spiral shape having a large effective cross-sectional area as shown in FIG. And so on. Further, a meander type inductor imitating a zigzag pattern as shown in FIG. 4 is also conceivable. The pattern shape of these inductors 4 can be formed by the above-described manufacturing method and the same pattern forming method as that of the antenna coil 2. Further, the pattern shape of the inductor 4 is not particularly limited as long as it is designed according to necessary inductance conditions. The arrangement of the inductor 4 when connecting to the antenna coil 2 is not limited to the vicinity of the IC chip 3 as shown in FIG. It doesn't matter.

  Actually, the antenna coil 2 and the inductor 4 are physically continuously connected and electrically coupled, but the non-contact data carrier antenna according to the present invention has the inductance of the antenna coil 2 as described above. The circuit is configured based on the idea of separating the component and the inductance component of the inductor 4, and the inductance component of the entire circuit is changed by changing only the inductor 4 while the design condition of the antenna body 2 is fixed. To be adjusted. In this case, the main body 2 of the antenna is designed so as to ensure the size (area, length, etc.) of the antenna for transmitting and receiving information via an electric field or a magnetic field. The inductance component can be adjusted by the inductor 4 without change. As a result, circuit design is facilitated, the degree of freedom in circuit design is improved, and the resonance frequency and Q value can be easily adjusted.

Explanatory drawing of the non-contact data carrier which shows an example of this invention. Explanatory drawing of the non-contact data carrier by the other example of this invention. Explanatory drawing of the non-contact data carrier by the other example of this invention. Explanatory drawing of the non-contact data carrier by the other example of this invention. Explanatory drawing of the conventional non-contact data carrier.

Explanation of symbols

1 Non-contact data carrier 2 Antenna or antenna body (antenna coil)
3 IC chip 4 Inductor 5 Base 6 Capacitor

Claims (2)

  A non-contact data carrier comprising an IC chip and an antenna and including a resonance circuit that resonates at a specific frequency, wherein an inductor is connected in series to the main body of the antenna.   In a method of manufacturing a non-contact data carrier comprising an IC chip and an antenna and incorporating a resonance circuit that resonates at a specific frequency, the antenna body is formed by a linear or planar pattern, and the pattern is extended. A method of manufacturing a non-contact data carrier, wherein an inductor is formed by a pattern forming method similar to that for the main body of the antenna.

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