JP4242537B2 - Antenna sheet and non-contact data carrier - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an antenna sheet having an antenna coil and a capacitor, and a non-contact type data carrier using the antenna sheet.
[0002]
[Prior art]
Non-contact data carriers having an antenna coil are used in shoplifting prevention devices, distribution systems, and the like. Such a non-contact type data carrier is used by being affixed to, for example, a product packaging box or the product itself.
[0003]
When manufacturing a non-contact type data carrier, an antenna coil can be formed by rotating a line pattern on an insulating base material (insulating base material).
When an antenna coil is manufactured, manufacturing variations generally occur. This manufacturing variation changes the characteristics of the antenna coil and affects the performance of the contactless data carrier.
[0004]
[Problems to be solved by the invention]
FIG. 1 is a configuration diagram illustrating an antenna sheet used for a contactless data carrier related to the present invention. A member such as an IC chip is mounted on the antenna sheet 10 to form a non-contact type data carrier.
The antenna sheet 10 includes an insulating base material 9, pads 11 and 12, an antenna coil 5, wiring patterns 15 </ b> A and 15 </ b> B, and a capacitor 15.
[0005]
The insulating base material 9 is made of, for example, a synthetic resin, and is a rectangular base material in FIG. On one surface of the insulating substrate 9, an antenna coil 5, pads 11, 12, a wiring pattern 15A, and conductor patterns 1A to 4A are formed.
A wiring pattern 15 </ b> B and conductor patterns 1 </ b> B to 4 </ b> B are formed on the other surface of the insulating substrate 9. The conductor patterns 1B to 4B are opposed to the corresponding conductor patterns 1A to 4A with the insulating base material 9 interposed therebetween.
[0006]
One pad 11 is connected to one end of the antenna coil 5.
The other pad 12 is connected to the other end of the antenna coil 5 through the through holes 13 and 14 and the wiring pattern 15B. The number of turns of the line pattern 6 from one pad 11 to the other pad 12 is six. The antenna coil 5 and the capacitor 15 constitute a resonance circuit.
[0007]
The four conductor patterns 1A to 4A constitute one electrode plate of the capacitor 15 and have the same area.
The conductor pattern 1A is connected to the conductor patterns 2A and 4A through a narrow wiring pattern.
The conductor pattern 2A is connected to the innermost line pattern of the antenna coil 5 via the wiring pattern 15A.
The conductor pattern 3A is connected to the conductor patterns 2A and 4A through a narrow wiring pattern.
[0008]
The four conductor patterns 1B to 4B constitute the other electrode plate of the capacitor 15 and have the same area.
The conductor pattern 1B is connected to the wiring pattern 15B, and is connected to the conductor patterns 2B and 4B through a narrow wiring pattern.
The conductor pattern 3B is connected to the conductor patterns 2B and 4B through a narrow wiring pattern.
[0009]
The wiring pattern connecting the conductor patterns 4A, 4B and the conductor patterns 1A, 1B is burned out by the laser beam, and the wiring pattern connecting the conductor patterns 4A, 4B and the conductor patterns 3A, 3B is burned out by the laser beam. The patterns 4A and 4B can be electrically separated to increase the capacitance of the capacitor 15 to 3/4 times the original.
Furthermore, the conductor pattern 4A, 4B, 3A, 3B is electrically cut off by burning out the wiring pattern connecting the conductor patterns 3A, 3B and the conductor patterns 2A, 2B with a laser beam, and the electrostatic capacity of the capacitor 15 is restored. Can be halved.
In this way, the capacitance of the capacitor 15 can be adjusted.
[0010]
As described above, a plurality of capacitor electrode patterns are formed on a non-contact data carrier or antenna sheet, and any one of the plurality of capacitor electrode patterns is selectively cut with a laser beam to electrostatically Tuning can be performed by adjusting the capacity.
In the antenna sheet 10 of FIG. 1, the capacitance of the capacitor 15 can be set to a value corresponding to the separation of a plurality of conductor patterns that constitute the capacitor 15. However, it is desired that the capacitance can be set in more stages, and further highly accurate tuning is possible.
[0011]
An object of the present invention is a non-contact type data carrier having a capacitor composed of electrode plates formed on both surfaces of an insulating base material, the non-contact type data carrier capable of improving tuning accuracy, and the non-contact type data carrier An object of the present invention is to provide an antenna sheet usable for a carrier.
[0012]
[Means for Solving the Problems]
An antenna sheet according to the present invention is an antenna sheet having an insulating base, an antenna coil formed on a surface of the insulating base, and a plurality of capacitors connected between a pair of ends of the antenna coil. Each of the plurality of capacitors is connected by wiring, and has an arbitrary cut portion provided on one or both electrode sides of the capacitor in the middle of the wiring. Further , in the plurality of capacitors , M electrode (M is an integer of 2 or more) formed on one surface of the insulating base material, and the other surface of the insulating base material, It includes the other electrode plate facing the M number of the one electrode plate through the insulating substrate, wherein the M pieces of one electrode plate and the other electrode plate constitute a capacitor, the capacitor Each of them is connected in parallel, and the areas of the M one electrode plates are different from each other.
[0013]
The other electrode plate has M electrode plates facing the corresponding one of the M electrode plates via the insulating base material, and the area of the M other electrode plate is: It is equal to 2 ^N times (N is an integer of 0 or more) of the minimum area of the areas of the M other electrode plates, and the area of the M one electrode plate is equal to one of the M number of electrode plates. The area is the same as 2 ^N times the minimum area of the electrode plates, and the areas of the one and the other electrode plates facing each other are the same .
[0014]
In the antenna sheet according to the present invention, more preferably, the M is an integer of 3 or more, and between the electrode plate having the smallest area among the M electrode plates and one end of the antenna coil. (M-1) contacts are provided, and the electrodes other than the electrode plate having the smallest area among the M electrode plates from the contact on the one end side with respect to the (M-1) contacts. The plates are connected in order of increasing area, and (M-1) contacts are provided between the electrode plate having the largest area among the M other electrode plates and the other end of the antenna coil. From the contact on the other end side to the (M-1) contacts, electrode plates other than the electrode plate having the largest area among the M other electrode plates are connected in order of decreasing area.
[0015]
In the antenna sheet according to the present invention, for example, the antenna coil and the capacitor form a resonance circuit, and a resonance frequency is set in advance by the capacitor composed of the one and the other electrode plates connected in parallel and the antenna coil. It is also possible to employ a configuration in which any one of the M electrode plates is electrically separated so as to achieve the frequency obtained.
[0016]
A non-contact data carrier according to the present invention includes an insulating base, an antenna coil formed on a surface of the insulating base, a plurality of capacitors connected between a pair of ends of the antenna coil, and the antenna coil. A contactless data carrier having members connected to both ends, wherein each of the plurality of capacitors is connected by wiring, and an arbitrary cutting point provided on one or both electrode sides of the capacitor Have in the middle of wiring. Further , in the plurality of capacitors , M electrode (M is an integer of 2 or more) formed on one surface of the insulating base material, and the other surface of the insulating base material, It includes the other electrode plate facing the M number of the one electrode plate through the insulating substrate, wherein the M pieces of one electrode plate and the other electrode plate constitute a capacitor, the capacitor Each of them is connected in parallel, and the areas of the M one electrode plates are different from each other.
[0017]
The other electrode plate has M electrode plates facing the corresponding one of the M electrode plates via the insulating base material, and the area of the M other electrode plate is: It is equal to 2 ^N times (N is an integer of 0 or more) of the minimum area of the areas of the M other electrode plates, and the area of the M one electrode plate is equal to one of the M number of electrode plates. The area is the same as 2 ^N times the minimum area of the electrode plates, and the areas of the one and the other electrode plates facing each other are the same .
[0018]
In the non-contact type data carrier according to the present invention, more preferably, the M is an integer of 3 or more, and an electrode plate having a minimum area among the one of the M electrode plates and one end of the antenna coil. (M-1) contacts are provided between the contacts, and the electrode plate having the smallest area among the M electrode plates from the contact on the one end side with respect to the (M-1) contacts. Are connected in order of increasing area, and (M−1) contacts are provided between the electrode plate having the largest area among the M other electrode plates and the other end of the antenna coil. An electrode plate other than the electrode plate with the largest area among the M other electrode plates is connected to the (M-1) contacts from the other end side in order of increasing area. ing.
[0019]
In the non-contact type data carrier according to the present invention, for example, the antenna coil and the capacitor form a resonance circuit, and the resonance frequency by the capacitor composed of the one and the other electrode plates connected in parallel and the antenna coil. May be configured such that any one of the M electrode plates is electrically separated so as to have a preset frequency.
[0020]
The non-contact type data carrier according to the present invention preferably further includes insulating first and second protective layers, and the antenna coil, the member and the one surface of the insulating base material The first protective layer is provided so as to cover the M electrode plates, and the second surface of the insulating base is covered with the second electrode plate so as to cover the other M electrode plates. The protective layer is provided.
[0022]
By electrically disconnecting one of the M electrode plates, the capacitance of the capacitor composed of the remaining one electrode plate and the other electrode plate can be reduced when the area of the M electrode plates is the same. Compared to this, it can be changed in multiple stages, and the tuning accuracy can be improved.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the accompanying drawings.
[0024]
Antenna sheet FIG. 2 is a schematic configuration diagram showing an embodiment of an antenna sheet according to the present invention.
The antenna sheet 20 includes an insulating base material 9, pads 11 and 12, an antenna coil 5, wiring patterns 25 </ b> A and 25 </ b> B, and a capacitor 25.
[0025]
The insulating base material 9 is made of a synthetic resin such as PET (polyethylene terephthalate), for example, and is a rectangular base material in FIG.
On one surface of the insulating substrate 9, the antenna coil 5, the pads 11 and 12, the wiring pattern 25A, and the conductor patterns 21A to 23A are formed. The antenna coil 5, the pads 11 and 12, the wiring pattern 25A, and the conductor patterns 21A to 23A are formed by etching using, for example, a resist material.
[0026]
On the other surface of the insulating base 9, wiring patterns 25B and 25C and conductor patterns 21B to 23B are formed. The wiring pattern 25B and the wiring pattern 25C are connected to each other. The wiring patterns 25B and 25C and the conductor patterns 21B to 23B are formed by etching using a resist material, for example.
The conductor patterns 21B to 23B are opposed to the corresponding conductor patterns 21A to 23A via the insulating base 9, and the sizes of the opposed conductor patterns are the same or substantially the same.
[0027]
One pad 11 is connected to one end of the antenna coil 5.
The other pad 12 is connected to the other end of the antenna coil 5 through the through holes 13 and 14 and the wiring pattern 25C. The number of turns of the line pattern 6 from one pad 11 to the other pad 12 is six. The antenna coil 5 and the capacitor 25 constitute a resonance circuit.
[0028]
The three conductor patterns 21 </ b> A to 23 </ b> A are connected to each other and constitute one electrode plate of the capacitor 25.
The conductor pattern 21A is connected to the pad 11 via the wiring pattern 25A. The area of the conductor pattern 21A is the smallest area among the conductor patterns 21A to 23A.
The area of the conductor pattern 22A is the same or substantially the same as twice the area of the conductor pattern 21A, and the area of the conductor pattern 23A is the same or substantially the same as four times the area of the conductor pattern 21A.
[0029]
The three conductor patterns 21B to 23B are connected to each other and constitute the other electrode plate of the capacitor 25.
The conductor pattern 21B is connected to the wiring pattern 25B. The area of the conductor pattern 21B is the smallest area among the conductor patterns 21B to 23B.
The area of the conductor pattern 22B is the same or substantially the same as twice the area of the conductor pattern 21B, and the area of the conductor pattern 23B is the same or substantially the same as four times the area of the conductor pattern 21B.
[0030]
The antenna coil 5 is composed of a line pattern 6 that circulates along the periphery of one surface of the insulating base material 9.
The conductor patterns 21 </ b> A to 23 </ b> A are formed in the central portion or the substantially central portion of one surface of the insulating base material 9.
The conductor patterns 21 </ b> B to 23 </ b> B are formed in the central portion or the substantially central portion of the other surface of the insulating base material 9.
[0031]
FIG. 3 is an enlarged view in which the conductor patterns 21A to 23A and 21B to 23B and the periphery thereof are enlarged in the antenna sheet 20 of FIG. The wiring pattern 25A has a wiring pattern 28A, and the wiring pattern 25B has a wiring pattern 28B. FIG. 4 is a schematic circuit diagram showing a connection relationship between the conductor patterns 21A to 23A and 21B to 23B and the pads 11 and 12 in FIG.
[0032]
The capacitor 25 has first to third capacitors 21 to 23.
The first capacitor 21 has a conductor pattern 21A constituting one electrode plate and a conductor pattern 21B constituting the other electrode plate.
The second capacitor 22 has a conductor pattern 22A constituting one electrode plate and a conductor pattern 22B constituting the other electrode plate.
The third capacitor 23 has a conductor pattern 23A constituting one electrode plate and a conductor pattern 23B constituting the other electrode plate.
[0033]
The conductor pattern 21A and the conductor pattern 22A are connected via a contact 26Q. The contact 26Q is connected to the contact 27Q via the wiring pattern 28A.
The conductor pattern 23A is connected to the contact point 27Q. The contact 27Q is connected to the pad 11 via the wiring pattern 25A.
[0034]
The conductor pattern 22B and the conductor pattern 23B are connected via a contact point 27P. The contact point 27P is connected to the contact point 26P through the wiring pattern 28B.
The conductor pattern 21B is connected to the contact 26P. The contact 26P is connected to the pad 12 via the wiring patterns 25B and 25C.
[0035]
In the circuit diagram of FIG. 4, 2 (= 3-1) contacts are provided between the conductor pattern 21A having the smallest area among the three conductor patterns 21A to 23A and the pad 11 connected to one end of the antenna coil 5. 26Q and 27Q are provided. The conductor patterns 22A and 23A other than the conductor pattern 21A having the smallest area among the three conductor patterns 21A to 23A are arranged in descending order from the contact 27Q on the one end side with respect to the two contacts 26Q and 27Q. It is connected.
[0036]
Further, 2 = (3-1) contacts 26P and 27P are provided between the conductor pattern 23B having the largest area among the three conductor patterns 21B to 23B and the pad 12 connected to the other end of the antenna coil 5. It is provided. The conductor patterns 21B and 22B other than the conductor pattern 23B having the largest area among the three conductor patterns 21B to 23B have a small area from the contact 26P on the other end side with respect to the two contacts 26P and 27P. Connected in order.
[0037]
FIG. 5 is a diagram illustrating the relationship between the equivalent capacitance between the pads 11 and 12, the cut position of the wiring (or wiring pattern), and the number of cut positions (the number of cuts) in the circuit diagram of FIG. FIG. The wiring is cut by, for example, burning the wiring by laser beam irradiation.
[0038]
(1): The wiring 28B from the contact point 26P to the contact point 27P is cut at a position indicated by a cross in the circuit diagram of FIG. It can be the same as the capacitance c. In this case, the number of cut points is one.
Thus, by providing the wiring pattern 28B between the contacts 26P and 27P, the capacitors 22 and 23 can be separated by cutting at one place.
[0039]
(2): The wiring from the contact 26P to the conductor pattern 21B and the wiring from the contact 27P to the conductor pattern 23B are cut at the locations indicated by the circles in the circuit diagram of FIG. The electrostatic capacity can be made twice (= 2c) the electrostatic capacity c of the first capacitor 21. In this case, the number of cut portions is two.
[0040]
(3): The wiring from the contact point 27P to the conductor pattern 23B is cut at the position indicated by the white square mark in the circuit diagram of FIG. The electrostatic capacity c can be three times (= 3c). In this case, the number of cut points is one.
[0041]
{Circle around (4)} The wiring 28A from the contact 26Q to the contact 27Q is cut at a position indicated by a white triangle in the circuit diagram of FIG. 4 times (= 4c). In this case, the number of cut points is one.
Thus, by providing the wiring pattern 28A between the contacts 26Q and 27Q, the capacitors 21 and 22 can be separated by cutting at one place.
[0042]
(5): The wiring from the contact point 27P to the conductor pattern 22B is cut at the location indicated by the black triangle in the circuit diagram of FIG. The capacitance c can be 5 times (= 5c). In this case, the number of cut points is one.
[0043]
(6): The wiring from the contact 26P to the conductor pattern 21B is cut at the location indicated by the black square in the circuit diagram of FIG. 6 times (= 6c). In this case, the number of cut points is one.
[0044]
{Circle around (7)} By not cutting the wiring from the pad 11 to the conductor patterns 21A to 23A and not cutting the wiring from the pad 12 to the conductor patterns 21B to 23B, the capacitance between the pads 11 and 12 can be reduced. The capacitance c of the capacitor 21 can be 7 times (= 7c). In this case, the number of cut points is zero.
[0045]
{Circle around (8)} By cutting the wiring from the pad 11 to the contact 27Q or the wiring from the pad 12 to the contact 26Q at the location indicated by the white or black hexagon in the circuit diagram of FIG. The capacitance between them can be made zero. In this case, the number of cut portions is 1 or 2.
[0046]
Thus, by separating any of the conductor patterns 21A to 23A and 21B to 23B connected in parallel using a laser beam or the like, the capacitance of the capacitor formed of the remaining conductor patterns connected in parallel is about 8 ( = 2 ³ ) It is possible to change the type, the tuning accuracy can be improved, and the resonance frequency by the capacitor and the antenna coil 5 can be brought close to or coincident with a preset set frequency.
[0047]
Non-contact type data carrier FIG. 6 is a schematic configuration diagram showing an embodiment of a non-contact type data carrier according to the present invention.
The non-contact type data carrier 30 has a configuration in which a member made of an IC chip 8 is mounted on the antenna sheet 20 of FIG. 2 and the IC chip 8 is connected to pads 11 and 12. The IC chip 8 is indicated by a rectangular frame in the drawing so that the state of the pads 11 and 12 can be understood.
[0048]
On the circuit forming surface of the IC chip 8, a terminal pair consisting of one electrode terminal and the other electrode terminal is formed. One electrode terminal corresponds to one pad 11, and the other electrode terminal corresponds to the other pad. 12 is supported.
The terminal pair of the IC chip 8 is connected to the pads 11 and 12 via bumps, and the IC chip 8 is flip-chip mounted.
[0049]
In this non-contact type data carrier 30, the antenna coil 5, the wiring pattern 25A, and the conductor patterns 21A to 23A are covered with an insulating film (insulating layer) made of an insulating resist material, and the pads 11 and 12 are exposed to expose the IC. The chip 8 may be connected, and further, only the connection part of the pads 11 and 12 with the IC chip 8 may be exposed and the other part may be covered with an insulating film.
[0050]
Insulating not shown so as to cover the pads 11 and 12, the antenna coil 5, the IC chip 8, the conductor patterns 21 </ b> A to 23 </ b> A, and the wiring pattern 25 </ b> A over the entire area of one surface of the insulating substrate 9. The protective layer is provided.
Further, an insulating protective layer (not shown) is provided on the entire other surface of the insulating base 9 so as to cover the conductor patterns 21B to 23B and the wiring pattern 25B.
And it affixes on the product packaging box or the product itself, and is used for a tag, a label, etc., for example.
In addition, the said embodiment is an illustration of this invention and this invention is not limited to the said embodiment.
[0051]
【The invention's effect】
In the non-contact type data carrier according to the present invention, by separating any of the plurality of electrode plates, the capacitance of the capacitor composed of the remaining one electrode plate and the other electrode plate can be reduced. Compared with the case where the area of a board is the same, it can change in multiple steps, and can improve the precision of tuning.
Further, according to the present invention, an antenna sheet that can be used for the non-contact data carrier can be provided.
[Brief description of the drawings]
FIG. 1 is a configuration diagram illustrating an antenna sheet related to the present invention.
FIG. 2 is a schematic configuration diagram showing an embodiment of an antenna sheet according to the present invention.
3 is an enlarged view of conductor patterns 21A to 23A, 21B to 23B and their surroundings in the antenna sheet 20 of FIG. 2;
4 is a schematic circuit diagram showing a connection relationship between conductor patterns 21A to 23A and 21B to 23B and pads 11 and 12 in FIG. 3;
5 is an explanatory diagram showing a relationship between an equivalent electrostatic capacity between pads 11 and 12, a cut position of wiring, and the number of cuts in the circuit diagram of FIG.
FIG. 6 is a schematic configuration diagram showing an embodiment of a contactless data carrier according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1A-4A, 1B-4B ... Conductor pattern, 5 ... Antenna coil, 6 ... Line pattern, 8 ... IC chip (member), 9 ... Insulation base material, 10, 20 ... Antenna sheet, 11, 12 ... Pad, 13, 14 ... Through hole, 15, 25 ... Capacitor, 15A, 15B, 25A, 25B, 25C, 28A, 28B ... Wiring pattern, 21 ... First capacitor, 22 ... Second capacitor, 23 ... Third capacitor, 21A -23A: Conductor pattern (one electrode plate), 21B-23B ... Conductor pattern (the other electrode plate), 26P, 26Q, 27P, 27Q ... Contact, 30 ... Non-contact data carrier.

Claims (7)

An insulating substrate;
An antenna coil formed on the surface of the insulating substrate;
An antenna sheet having a plurality of capacitors connected between a pair of ends of the antenna coil,
Each of the plurality of capacitors is connected by wiring,
The middle of the wiring, possess any cut part provided on one or both of the electrode side of the capacitor,
In the plurality of capacitors,
M electrode plates (M is an integer of 2 or more) formed on one surface of the insulating substrate;
The other electrode plate formed on the other surface of the insulating base material and facing the M electrode plates through the insulating base material;
Contains
The M one electrode plate and the other electrode plate constitute a capacitor, and each of the capacitors is connected in parallel.
The areas of the M one electrode plates are different from each other,
The other electrode plate has M electrode plates facing the corresponding one of the M electrode plates via the insulating base, and the area of the M other electrode plates is the M 2 ^N of the minimum area of the other electrode plate area Times (N is an integer of 0 or more),
The area of the one of the M electrode plates is 2 ^N which is the minimum area of the areas of the one of the M electrode plates. Times the same,
The antenna sheet has the same area of the one and the other electrode plates facing each other . M is an integer of 3 or more,
(M-1) contacts are provided between the electrode plate having the smallest area among the M electrode plates and one end of the antenna coil, and with respect to the (M-1) contacts. From the contact on the one end side, electrode plates other than the electrode plate with the smallest area among the M one electrode plates are connected in order of increasing area,
(M-1) contacts are provided between the electrode plate having the largest area among the M other electrode plates and the other end of the antenna coil, and the (M-1) contacts are connected to the (M-1) contacts. from the contact of the other end against, the M other antenna sheet according to claim 1, wherein the electrode plates other than the electrode plate with the largest area is connected to the ascending order of the area of the electrode plate. The antenna coil and the capacitor form a resonance circuit,
Any one of the M electrode plates is electrically disconnected so that a resonance frequency by the capacitor composed of the one and the other electrode plates connected in parallel and the antenna coil becomes a preset frequency. antenna sheet according to any one of claims 1-2. An insulating substrate;
An antenna coil formed on the surface of the insulating substrate;
A non-contact type data carrier having a plurality of capacitors connected between a pair of ends of the antenna coil, and members connected to both ends of the antenna coil,
Each of the plurality of capacitors is connected by wiring,
Possess any cut part provided on one or both of the electrode side of the capacitor in the middle of the wiring,
In the plurality of capacitors,
M electrode plates (M is an integer of 2 or more) formed on one surface of the insulating substrate;
The other electrode plate formed on the other surface of the insulating base material and facing the M electrode plates through the insulating base material;
Contains
The M one electrode plate and the other electrode plate constitute a capacitor, and each of the capacitors is connected in parallel.
The areas of the M one electrode plates are different from each other,
The other electrode plate has M electrode plates facing the corresponding one of the M electrode plates via the insulating base, and the area of the M other electrode plates is the M 2 ^N of the minimum area of the other electrode plate area Times (N is an integer of 0 or more),
The area of the one of the M electrode plates is 2 ^N which is the minimum area of the areas of the one of the M electrode plates. Times the same,
A data carrier in which areas of the one and the other electrode plates facing each other are the same . M is an integer of 3 or more,
(M-1) contacts are provided between the electrode plate having the smallest area among the M electrode plates and one end of the antenna coil, and with respect to the (M-1) contacts. From the contact on the one end side, electrode plates other than the electrode plate with the smallest area among the M one electrode plates are connected in order of increasing area,
(M-1) contacts are provided between the electrode plate having the largest area among the M other electrode plates and the other end of the antenna coil, and the (M-1) contacts are connected to the (M-1) contacts. 5. The non-contact type data carrier according to claim 4 , wherein electrode plates other than the electrode plate having the largest area among the M other electrode plates are connected from the contact on the other end side in order of decreasing area. The antenna coil and the capacitor form a resonance circuit,
Any one of the M electrode plates is electrically disconnected so that a resonance frequency by the capacitor composed of the one and the other electrode plates connected in parallel and the antenna coil becomes a preset frequency. The non-contact type data carrier according to any one of claims 4 to 5 . An insulating first and second protective layer;
The first protective layer is provided on the one surface of the insulating base so as to cover the antenna coil, the member, and the M one electrode plate,
The non-contact type data carrier according to any one of claims 4 to 6 , wherein the second protective layer is provided on the other surface of the insulating base so as to cover the M other electrode plates. .

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