JP2010039531A - Pattern for authentication apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pattern for an authentication apparatus which can make the exterior shape of film smaller by reducing the number of wiring patterns and the number of terminals in the authentication apparatus for verification of the information received from an IC card and the information of the operated switch. <P>SOLUTION: An antenna pattern for receiving the electric waves which are transmitted from the IC card on a film is commonly used as a ground pattern arranged around a switch of a capacitive system for protecting the switch and the electrostatic capacity. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention is a pattern of an authentication device provided with an electrostatic capacity type switch for inputting a number on a film surface, an antenna for transmitting a password registered in advance to an IC card by radio waves, and an antenna for receiving it. The card receives radio waves emitted from an antenna provided in the authentication device by an antenna provided in the IC card, and an electromotive force is generated by the resonance action of the antenna. The tag provided in the IC card is activated by the generated electromotive force, and the password registered in advance in the IC tag is oscillated from the antenna in the IC card and transmitted to the antenna provided in the authentication device. The authentication device reads the radio wave from the ic card with the antenna, stores the password in a memory in the authentication device, and operates the capacitance type switch provided in the authentication device to confirm the password. Thus, the personal identification number is input, transmitted from the IC card by radio waves and stored in the memory, and the personal identification number input by the capacitive switch is transmitted from the IC card by radio waves, Authentication is performed by checking against what is stored in. In addition, the electrostatic capacitance type switch is configured such that a ground wire is arranged around the electrostatic capacitance type switch and connected to the ground, whereby electrostatic capacitance is applied to the electrostatic capacitance type switch. In particular, the present invention relates to a pattern of an authentication device that can prevent a malfunction in which a capacitance type switch is turned on even if an operator's finger or the like is not touched.

Authentication of the password registered in advance in the IC card is performed by causing the authentication device to recognize the ic card by touching the authentication device and causing the recognition device to read the password.

  As shown in FIG. 1, the Ic card 1 includes an IC tag 2 and an antenna 3. The IC tag 2 has a function of holding a personal identification number and generating a radio wave 4. The personal identification number written on the IC tag 2 is oscillated through the antenna 3 connected to the IC tag 2 to the authentication device 5. Sending.

  As shown in FIG. 2, the authentication device 5 includes an antenna 38 for receiving the radio wave 4 transmitted from the antenna 3 of the IC card 1 and a converter (hereinafter referred to as digital) that converts the radio wave 4 received from the antenna 38 into digital data. It is comprised from the memory 7 which stores the data converted by the converter 6.). Further, the four switches 11 are selected by the switcher 12, and the frequency generated by the capacitor 13 and the resistor 14 is connected to the input capture 15, and the CPU (not shown) reads the capacitance of the selected switch in advance. The switch is turned on when the set ON threshold is exceeded with respect to the set on and OFF thresholds stored in the memory 7, and the switch is turned off when the set off threshold is not exceeded.

  The operation of the authentication apparatus shown in FIG. 2 is performed by using the code number written on the tag 2 of the ic card 1 as data to be placed on the radio wave in the tag 2, and using the antenna 38 provided in the authentication apparatus 5. After receiving the radio wave 4 as the number data and reading it into the memory 7, the operator reads the personal identification number with the four switches 11 and collates it with the number stored in the memory 7. Authenticate. As an example, if the PIN is 4 digits of 1234, the 1234 numbers written on the tag of the ic card are used as data that can be placed on the radio wave in the tag as described above, and the antenna 38 receives the radio wave. After that, the digital converter 6 converts it into 4 digits of 1234 and stores it in the memory 7. Next, with the four switches 11, the switches are assigned from the left as numbers 1, 2, 3, and 4, and the operator touches the four switches 11 in the order 1, 2, 3, and 4 in order. The number of the switch 11 is input, and the 4 digits of the 1234 input by the operator are compared with the 4 digits of the 1234 stored in the memory, and the password is the same, so that the operator can be authenticated. it can.

  When the sensor unit 36 of the authentication device 5 shown in FIG. 2 is made of a film, the antenna 38 is formed by printing a conductive material on the surface of the film 8 shown in FIG. The film 8 is provided with terminals 1 and 2 for connection with the digital converter 6 arranged side by side below the film 8. The wiring pattern 37 which is an antenna 38 is arranged around the outer shape 9 of the film from the left side of the terminal 1 to form a coil shape by making two turns, thereby generating a magnetic field due to the induced electromotive force and generating the radio wave 4 oscillated from the IC card 1. Receive. The first round of the wiring pattern 37 passes between the terminals 1 and 2, and the second round is arranged so as to be connected to the right side of the terminal 2. Further, + marks 23 serving as a reference used when the films are bonded are provided at two corners of the printing surface 20 of the film 8.

  When the electrostatic capacitance 16 (see FIG. 2) that turns on the four switches is applied to the four switches 11, the four switches 11 are turned on even if the finger of the operator is not touched. Will cause a malfunction. The four switches 11 are surrounded by a wiring pattern 10 and connected to a ground 17. The electrostatic capacitance 16 is applied to the wiring pattern 10 surrounding the four switches 11 so that the electrostatic capacitance 16 is transmitted to the connected ground 17 so that the static electricity does not directly enter the four switches. By doing so, malfunction due to static electricity capacitance 16 is prevented.

  As shown in FIG. 4, four switches 11 are provided on the surface of the film 8, and the numbers of the four switches 11 are numbered 1 to 4. Terminals 1 to 4 for connecting the four switches 11 and the switch 12 are provided below the four switches 11. The wiring pattern 10 is extended from the lower side of the four switches 11 and connected from the terminal 1 to the upper side of the terminal 4. The wiring pattern 37 connected to the ground 17 via the terminal 5 and the terminal 6 has the terminal 6 on the left side of the terminal 1 and the terminal 6 on the right side of the terminal 4, and a film around the four switches 11 from the left side of the terminal 5. Turn along the outer shape of 8 and connect on the right side of the terminal 6.

  As shown in FIG. 5, a printing surface 20 of the film 18 on which the antenna is printed and a non-printing surface 21 of the film 19 on which the switch is printed are bonded together with a double-sided adhesive sheet 22. The bonding of the printing surface 20 of the film 18 on which the antenna is printed and the non-printing surface of the film 19 on which the switch is printed is performed by printing the + mark 23 and the switch serving as a reference position provided on the film 18 on which the antenna is printed. After aligning the + mark 23, which is the reference position provided on the film 19, in the direction of the arrow while pressing the non-printing surface of the film 18 on which the antenna is printed with the roller 24 so that air does not enter between the films. Move and do. By bonding the two films of the film 18 on which the antenna is printed and the film 19 on which the switch is printed, the wiring pattern 37, the terminal 7, the terminal 8, the four switches 11, the wiring pattern 10, and the antenna 38 are bonded. The wiring pattern 37 of the ground 17 and the terminal 1 to the terminal 6 are formed.

Further, as shown in FIG. 6, the wiring pattern 37 as the antenna 38, the terminals 7 and 8 for connection to the digital converter 6, the wiring pattern 10 of the four switches 11, and the wiring pattern 37 of the ground 17 When the terminals 1 to 6 are formed on the same surface using a single film 8, the conductive material is printed on the surface of the film 8. Four switches 11 are provided on the same surface of the film 8, and the numbers of the switches are numbered 1 to 4. Terminals 1 to 4 for connecting each switch to the switch 12 are provided side by side below the switch. From the lower side of the four switches 11, the wiring pattern 10 connects the terminal 1 for connecting to the switch 12 to the upper side of the terminal 4. The terminal 5 and the terminal 6 for connecting to the ground 17 are provided with the terminal 5 on the left side of the terminal 1 and the terminal 6 on the right side of the terminal 4, and a wiring pattern 37 is provided from the left side of the terminal 5. Turn along the outer shape 9 of the film and connect to the right side of the terminal 6. Next, a terminal 7 and a terminal 8 for connecting to the digital converter 6 are provided side by side below the terminals 2 and 3. The wiring pattern 37 which is the antenna 38 is arranged around the outer shape 9 of the film from the left side of the terminal 7 to form a coil shape by making two turns, thereby generating a magnetic field due to the induced electromotive force and generating the radio wave 4 oscillated from the IC card 1. Receive. The first round of the wiring pattern 37 passes between the terminals 7 and 8, and the second round is connected to the right side of the terminal 8. It is known that the wiring pattern 37 as the antenna 38, the terminal 7, the terminal 8, the four switches 11, the wiring pattern 10, the wiring pattern 37 of the ground 17 and the terminal 1 to the terminal 6 can be arranged on the same surface of the film 8. ing.
Japanese Patent Application Laid-Open No. 2005-049882.

  As shown in FIG. 5, the film is bonded using the roller 24. However, the film is thin and has no waist, and the film is bent, so that air bubbles are likely to enter between the films. Currently.

  When the above-described film 18 on which the antenna is printed and the film 19 on which the switch is printed are bonded with the double-sided adhesive sheet 22, bubbles 30 enter as shown in FIG. 7, and the capacitance 28 between the switch 26 and the finger 27. Compared with the case where there is no bubble 30, the distance 31 between the switch 26 and the finger 27 becomes longer, and the obtained capacitance value becomes smaller due to the difference in dielectric constant between the case where there is the bubble 30 and the case where there is no bubble 30. Since the capacitance switch 28 between the finger 27 and the switch 26 determines the threshold value of the capacitor 28 for turning on the switch and the threshold value of the capacitor 28 for turning off the switch. The threshold value which becomes on and off must be adjusted for each film 8 due to the bubble 30 entering, and the present situation is that the threshold value cannot be unified.

  As shown in FIG. 6, when the four switches 11 and the terminals 1 to 4 and the wiring pattern 10 are formed on one film 8, the film 29 has a thickness 29 (see FIG. 7). Since the switch 26 and the finger 27 have the same capacity, the thresholds for determining whether the switch is ON or OFF can be unified. However, the wiring pattern 37 that is the antenna 38 is designed so that the four switches 11 and the wiring pattern 37 of the ground 17 that surrounds the four switches 11 are not subject to magnetic field interference caused by the induced electromotive force oscillated from the antenna 38. Since the space of the dimension A25 is provided around the wiring pattern 37 of the ground 17, there is a problem that the outer shape of the film 8 becomes large.

  An information oscillation source transmits information by radio waves, and an antenna pattern for receiving the radio waves, a plurality of capacitance switches for an operator to input information, and a capacitance switch are provided so as to surround the capacitance switches. A memory for storing information on a capacitance switch pressed by an operator among the plurality of capacitance switches, and information transmitted by radio waves from the information oscillation source. An authentication device for verifying and authenticating the two stored information, the authentication device having an antenna for receiving radio waves oscillated by the information oscillation source on a single film surface, The present invention proposes a pattern of an authentication device provided with a wiring pattern that shares a ground line provided so as to surround a capacitance switch.

In the present invention, when electrostatic capacitance is applied to a switch that connects a wiring pattern of an antenna for receiving radio waves transmitted from an IC card and a digital converter to a single film, and a capacitive switch. In order to prevent the malfunction of the capacitance type switch being turned on even when the operator's finger is not touching, the ground wiring pattern arranged around the capacitance type switch is connected to the ground. By sharing the terminals, the number of wiring patterns and the number of terminals can be reduced, and the outer shape of the film can be reduced.

  In the present invention, as shown in FIG. 8, four switches 11 are provided on the surface of the film 8, and the numbers of the four switches 11 are numbered 1 to 4. Terminals 1 to 4 for connection to the switch 12 are provided at locations below the four switches 11. Capacitance switches No. 1 to No. 4 and the above-described terminals 1 to 4 are connected by a wiring pattern 10. When the wiring pattern 37, which is the antenna 38, is connected to the digital converter 6, the terminals 5 and 6 and the electrostatic capacitance 16 are applied to the film 8, even if the operator's finger or the like is not touched. In order to prevent a malfunction in which the individual switches 11 are turned on, the ground wiring pattern 37 arranged around the four switches 11 is shared with the terminal 5 and the terminal 6 for connecting to the ground 17. On the left side, the terminal 6 is provided on the right side of the terminal 4. A wiring pattern 37 sharing the antenna 38 and the ground 17 is arranged around the outer shape 9 of the film from the left side of the terminal 5 and is formed in a coil shape by generating a magnetic field due to an induced electromotive force and is oscillated from the IC card 1. Radio wave 4 is received. The first round of the wiring pattern 37 passes between the terminals 4 and 6, and the second round is connected to the right side of the terminals 6. The number of the terminals 5, 6 and the wiring pattern 37 sharing the antenna 38 and the ground 17 is one, and the outer shape of the film 8 can be reduced.

In the present invention, a PET film is used and a conductive material is printed on the surface of the film 8 as shown in FIG. 8, and the four switches 11, the terminals 1 to 6 and the wiring pattern 37 are provided.
The use of the wiring pattern 37 sharing the antenna 38 and the ground 17 of the present invention will be described with reference to FIG. As shown in FIG. 9, the control unit 32 of the authentication device 5 includes a digital converter 6 that converts the radio wave 4 from the IC card 1 into digital data with an antenna 38 formed of a conductive material on the surface of the film 8; A memory 7 for storing data converted by the digital converter 6, a switch 12 for selecting four switches 11 formed of a conductive material on the surface of the film 8, a switch and a finger selected by the switch 12 A capacitor 13 and a resistor 14 for converting the capacitance of the antenna into a frequency, an input capture 15 for reading the converted frequency, a ground 17 for releasing the electrostatic capacitance 16, and a wiring pattern 37 sharing the antenna 38 and the ground 17 are digitally converted. The selector 34, the input capture 15, and the selector 34 that perform switching for connection to the device 6 or the ground 17 are controlled. And it is configured from PU33.

  As shown in FIG. 9, the terminals 1 to 4 are connected to the switch 12, and the terminals 5 and 6 are connected to the selector 34. The selector 34 performs switching to connect the terminal 5 and the terminal 6 to the digital converter 6 or connect the terminal 5 and the terminal 6 to the ground 17 according to the selection signal 35 of the CPU 33. When the authentication device 5 receives the radio wave 4 from the IC card 1, the selector 34 is connected to the digital converter 6 with the selection signal 35 of the CPU 33, and the wiring pattern 37 is used as the antenna 38. The radio wave 4 from the IC card 1 is received, converted into digital data by the digital converter 6 and stored in the memory 7. Further, when using a capacitance type switch, the selector 34 is connected to the ground 17 by the selection signal 35 of the CPU 33, the wiring pattern 37 is used as the ground 17, and the electrostatic capacitance 16 is used. This prevents malfunctioning of the switch.

IC card diagram Configuration diagram of authentication device Antenna pattern of authentication device Capacitance type switch pattern diagram Film lamination diagram Pattern diagram with one film Capacity diagram of finger and switch Shared pattern diagram Connection configuration diagram

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 IC card 2 IC tag 3 Antenna 4 Radio wave 5 Authentication apparatus 6 Digital converter 7 Memory 8 Film 9 Film outline 10 Wiring pattern 11 Four switches 12 Switcher 13 Capacitor 14 Resistance 15 Input capture 16 Electrostatic capacity 17 Ground 18 Film with antenna printed 19 Film printed with switch 20 Printing surface 21 Non-printing surface 22 Double-sided adhesive sheet 23 + Mark 24 Roller 25 Dimension a
26 Switch 27 Finger 28 Capacity 29 Thickness 30 Bubble 31 Distance 32 Controller 33 CPU
34 selector 35 selection signal 36 sensor unit 37 wiring pattern 38 antenna

Claims (1)

An information oscillation source transmits information by radio waves, and an antenna pattern for receiving the radio waves, a plurality of capacitance switches for an operator to input information, and a capacitance switch are provided so as to surround the capacitance switches. A memory for storing information on a capacitance switch operated by an operator among the plurality of capacitance switches, and information transmitted by radio waves from the information oscillation source. An authentication device for verifying and authenticating the two stored information, the authentication device having an antenna for receiving radio waves oscillated by the information oscillation source on a single film surface, A pattern of an authentication device, characterized in that a wiring pattern sharing a ground line provided so as to surround a capacitance switch is provided.