KR20230036939A - Counterfeit fingerprint identification device - Google Patents

Abstract

The present invention relates to a counterfeit fingerprint identification device, comprising: an electrostatic fingerprint sensor that scans a fingerprint using a semiconductor device that detects capacitance or electrical conduction to obtain image information of the fingerprint; and an ultrasonic sensor that detects the presence or absence of finger bones and scans blood flow using a pulse echo method to determine whether it is a counterfeit fingerprint or a real fingerprint. By attaching the ultrasonic sensor to the electrostatic fingerprint sensor, counterfeit fingerprints can be identified by detecting and comparing the features thereof, making it easy to identify counterfeit fingerprints. Also, it is easy to identify counterfeit fingerprints because the determination is performed by using the pulse echo method based on the observation on the presence or absence of bones in the finger joints and receiving half-dispersed waves from the blood flow.

Description

Counterfeit fingerprint identification device

The present invention relates to a fake fingerprint identification device, and more particularly, to a fake fingerprint identification device capable of identifying a fake fingerprint by attaching an ultrasonic sensor to a capacitive fingerprint sensor to detect and compare features.

In general, ridges of fingerprints are formed along the location of sweat glands in a finger or toe among body parts of the human body, and valleys are formed between the ridges. In other words, the ridge of a fingerprint can be said to be a skin ridge along a sweat gland formed on a finger or toe. Therefore, sweat pores are formed on the ridges of the fingerprint to sweat the sweat generated by the sweat glands.

These fingerprints, even identical twins, are different from each other and can be an identification means to uniquely identify a specific person. However, conventionally, these fingerprints have been used as an authentication means rather than an identification means for identifying a specific person. That is, in the conventional fingerprint authentication, a person to be authenticated is identified using a separate medium or an ID, and then the fingerprint is authenticated to authenticate whether or not the person is the person. Therefore, attempts to steal others by forging fingerprints are continuing.

However, forgery of fingerprints is relatively easy. When fingerprint recognition is attempted by copying a fingerprint through a material having physical, chemical, and electrical properties similar to the human epidermis, conventionally proposed fingerprint recognition technologies have a very difficult problem in excluding such simulated fingerprints. For example, when a fingerprint is copied using gummi, which is very similar to the composition of the epidermis of the human body, it is very difficult to exclude such a simulated fingerprint through conventional fingerprint recognition technology.

As a technique for excluding such simulated fingerprints, there are, for example, Japanese Patent Laid-Open No. 2000-123143, Japanese Laid-Open Patent No. 10-302047, Japanese Laid-Open Patent No. 2000-194848, and Japanese Laid-Open Patent No. 2000-172833.

However, in the technology disclosed in Japanese Patent Laid-Open No. 2000-123143 or Japanese Patent Laid-Open No. 10-302047, whether or not the subject is a living body is determined based on the current value, capacitance, and electrical resistance of the subject. It is difficult to exclude simulated fingerprints using materials with similar physical, chemical, and electrical characteristics, and in the technology disclosed in Japanese Patent Laid-Open No. 10-370295, a fake fingerprint is determined by whether or not a capacitive sensor responds. Since the technology disclosed in Patent Publication No. 2000-172833 only determines whether or not it is a living body by the frequency characteristic of impedance, which is an electrical characteristic, a simulated fingerprint using a material with physical, chemical, and electrical characteristics similar to that of the human epidermis. is difficult to rule out.

That is, the impedance of the human body shows a large difference according to age, gender, each part of the human body, and water content. In general, about 2500 Ω is used as a standard to determine the impedance of the human body, but in reality, it shows a very large difference from person to person. For example, an impedance of about 10,000 Ω is measured for a hand of a worker who works with a tool, and an impedance of about 1,000 Ω is measured for a soft skin like an office worker's hand, so the impedance of the human body fluctuates considerably. Therefore, although it may be relatively easy to determine whether or not a living body is a living body simply by using impedance, it is very difficult to determine whether or not a specific user's impedance is determined by quantifying the impedance of a specific user.

As prior literature for solving the above problems, Korean Patent Publication No. 2017-0115225 (published on October 17, 2017) "a fingerprint recognition module, an electronic device to which it is applied, and a method for manufacturing a sound wave control member" is a fingerprint recognition module. a contact member to be contacted; a transducer outputting an ultrasonic signal to the contact member and receiving the ultrasonic signal reflected by the contact member; an impedance matching member filled between the contact member and the transducer to transmit an ultrasonic signal between the contact member and the transducer; A penetrating portion is provided between the contact member and the transducer so that the contact member and the transducer are connected via the impedance matching member. a sound wave control member that induces resonance; and a signal processing unit electrically connected to the transducer and sensing a fingerprint according to a received ultrasonic signal.

It is possible to obtain a high-resolution three-dimensional image from the dermal layer to the epidermal layer, and to distinguish between real human fingerprints and fake fingerprints to maximize security due to fake fingerprints. In the case of a fingerprint made of the same material as fake skin, there is a problem in recognizing it as a real fingerprint.

Japanese Laid-open Patent No. 2000-123143 Japanese Unexamined Patent Publication No. 10-302047 Japanese Laid-open Patent No. 2000-194848 Japanese Laid-open Patent No. 2000-172833 Korean Patent Publication No. 2017-0115225

In order to solve the above problems, the present invention attaches an ultrasonic sensor to a capacitive fingerprint sensor to detect and compare features to identify counterfeit fingerprints, as well as to determine forgery using a pulse echo method, and to determine finger knuckles. Provided is a fake fingerprint identification device that determines whether a fingerprint is a fake fingerprint or a real fingerprint by scanning the presence or absence of bones and blood flow.

The present invention is a means for achieving the above object,

an electrostatic fingerprint sensor that scans a fingerprint by means of a semiconductor device that detects capacitance or electrical conduction so as to obtain image information of a fingerprint; It provides a fake fingerprint identification device characterized in that it is a fingerprint sensor consisting of; an ultrasonic sensor that scans the presence or absence of a finger bone and blood flow in a pulse echo method to determine whether it is a fake fingerprint or a real fingerprint.

The ultrasonic sensor of the present invention includes a lead zirconate titanate (PZT) piezoelectric body installed between switching elements; A plurality of switching elements formed to be spaced apart from each other on the top of the PCB installed inside the fingerprint card; It is characterized in that it includes; a film installed between the electrode installed in the lower direction of the PZT piezoelectric body and the PCB.

The ultrasonic sensor of the present invention is characterized in that it is installed in epoxy molding (or EMC) formed between the upper panel and the lower panel of the fingerprint card.

The ultrasonic sensor of the present invention is characterized in that it is installed in a bezel formed between the upper panel and the lower panel of the fingerprint card.

The present invention has an effect of facilitating identification of fake fingerprints because it is possible to identify counterfeit fingerprints by detecting and comparing features by attaching an ultrasonic sensor to an electrostatic type fingerprint sensor.

In addition, since the present invention determines forgery by using the pulse echo method for the bones and blood flow of the knuckles, it is easy to identify fake fingerprints.

In addition, since the present invention is manufactured by inserting the ultrasonic sensor into the molding of the fingerprint sensor or the bezel of the fingerprint card, the manufacturing cost is lowered and mass production is easy.

In addition, the present invention applies a current necessary for operation in a bias voltage unit through a bias tee to a PZT piezoelectric body, and applies a frequency applied from a signal generator through a bias tee to maintain high impedance, so that ultrasonic wave There is an effect of accurately determining whether a fingerprint is a fake fingerprint or a real fingerprint by determining the presence or absence of a finger bone and scanning blood flow through transmission and reception.

1 is a view showing a state in which a counterfeit fingerprint identification device is installed in the fingerprint card of the present invention.
Figure 2 is a view schematically showing the forged fingerprint identification device of Figure 1;
Figure 3 is a cross-sectional view showing the configuration of the ultrasonic sensor shown in Figure 2;
Figure 4 is a view showing another embodiment of the forged fingerprint identification device of the present invention.
5 is a diagram showing the configuration of a circuit for transmitting and receiving ultrasonic waves of a pulse echo method of an ultrasonic sensor of the forged fingerprint identification device shown in FIG. 3;

Hereinafter, it should be noted that the technical terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention, and the technical terms used in the present invention have a particularly different meaning in the present invention. Unless defined, it should be interpreted in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs, and should not be interpreted in an excessively comprehensive meaning or an excessively reduced meaning.

In addition, when the technical terms used in the present invention are incorrect technical terms that do not accurately express the spirit of the present invention, they should be replaced with technical terms that those skilled in the art can correctly understand. In addition, general terms used in the present invention should be interpreted as defined in advance or according to context, and should not be interpreted in an excessively reduced sense.

In addition, singular expressions used in the present invention include plural expressions unless the context clearly indicates otherwise, for example, terms such as “consisting of” or “comprising” refer to various components described in the invention, or It should not be construed as necessarily including all of the various steps, and it should be construed that some components or some steps may not be included, or additional components or steps may be further included.

The configuration of the forged fingerprint identification device according to the present invention will be described.

The counterfeit fingerprint identification device according to the present invention is a semiconductor device method that detects capacitance or electrical conduction so as to acquire image information of a finger print. It is characterized in that it detects the presence or absence of finger bones and scans blood flow to determine whether it is a fake fingerprint.

The forged fingerprint identification device of the present invention having the above features will be described in detail with reference to the accompanying drawings.

1 is a view showing a state in which a counterfeit fingerprint identification device is installed in the fingerprint card of the present invention, FIG. 2 is a diagram schematically showing the counterfeit fingerprint identification device of FIG. 1, and FIG. 3 is an ultrasonic sensor shown in FIG. Figure 4 is a cross-sectional view showing the configuration of, Figure 4 is a view showing another embodiment of the counterfeit fingerprint identification device of the present invention, Figure 5 is a pulse echo type ultrasonic wave of the ultrasonic sensor of the counterfeit fingerprint identification device shown in Figure 3 It is a diagram showing the configuration of a circuit for transmitting and receiving.

1 to 5, the forged fingerprint identification device of the present invention is composed of a fingerprint sensor 100 including an electrostatic fingerprint sensor 110 and an ultrasonic sensor 120.

The electrostatic fingerprint sensor 110 recognizes a fingerprint as a difference in capacitance between ridges and valleys of the fingerprint. In addition, the fingerprint scanned by the electrostatic fingerprint sensor 110 is applied to the PCB 20 so that it can be compared with pre-stored data and judged.

The ultrasonic sensor 120 is a plurality of switching elements 122 formed at a distance from the top of the PCB 20 installed on the fingerprint card 10 and a PZT (installed between the plurality of switching elements 122) A film 123 made of an insulating material between the lead zirconate titanate piezoelectric body 121 and the '-' electrode 122-2 of the switching element 122 installed below the PZT piezoelectric body 121 and the PCB 20 ) is installed.

The '+' electrode 122-1 of the switching element 122 is installed on the upper part of the PZT piezoelectric body 121, and the '-' electrode 122-2 of the switching element 122 is installed on the lower part of the PZT piezoelectric body 121. The '+' electrode 122-1 is located at a distance from the PZT piezoelectric body 121, and the '-' electrode 122-2 is installed in close contact with the PZT piezoelectric body 121, As the '+' electrode 122-1 adheres to the PZT piezoelectric body 121 by the pressure applied from , it can play a switching role while pressurizing the PZT piezoelectric body 121.

Only one side of the '+' electrode 122-1 is soldered (124) to the PZT piezoelectric body 121, and only one side of the '-' electrode 122-2 is also soldered (124) to the PZT piezoelectric body 121, so that switching works. make it possible to

By the current of the bias voltage unit 140 applied to the PZT piezoelectric body 121, ultrasonic waves are transmitted and received, and by the supplied current, the presence or absence of the finger bones is determined by the pulse echo method and the blood flow is scanned. It is possible to determine whether it is a real fingerprint.

The PZT piezoelectric body 121 is electrically connected to the bias tee 130, and the bias tee 130 is electrically connected to the bias voltage unit 140 to supply current, and also The tee 130 is connected to the switching element 122 composed of the '+' electrode 122-1 and the '-' electrode 122-2 so that the pulse applied from the signal generator 150 can be applied, The switching element 122 is electrically connected to a signal generator 150 to apply a frequency.

The switching element 122 is electrically connected to the amplifier 160 to amplify the capacitance signal applied through the bias tee 130 and the capacitance signal applied through the switching element 122, and amplify the capacitance signal. The signal is applied to the PCB 20.

The ultrasonic sensor 120 configured as described above is installed in an epoxy resin (epoxy molding or EMC (Epoxy Molding Compound)) 170 or is installed in the bezel 180 of the fingerprint sensor 100 to use a pulse echo method for finger bones. It determines the presence or absence of blood and scans the blood flow.

In the drawing, reference numeral 125 is a via hole, and the via hole 125 makes an electrical connection with the PCB 20 .

The process of determining a fake fingerprint by the forged fingerprint identification device of the present invention configured as described above will be described.

When a user places a fingerprint on the fingerprint sensor 100 to recognize a fingerprint, the fingerprint is scanned by the change in capacitance by the electrostatic fingerprint sensor 110 . When the fingerprint is scanned, the '+' electrode 122-1 of the switching element 122 of the ultrasonic sensor 120 is pressed and comes into contact with the PZT piezoelectric body 121, and the PZT piezoelectric body 121 and It is switched with the integrally formed '-' electrode 122-2.

The switching element 122 is switched by the '+' electrode 122-1 and the '-' electrode 122-2, and a pulse signal is generated from the signal generator 150 by the above switching, is applied to the PZT piezoelectric body 121 through and transmits ultrasonic waves. At this time, the transmitted ultrasonic waves are generated by applying more than 113 to 167 kHz, V _DC =20V & V _{AC = 20Vp-p} to the two opposite '+' electrodes 122-1 and '-' electrodes 122-2, and transmission It is done.

In addition, upon reception of the ultrasonic waves reflected by the finger bones and blood flow, the '-' electrode 122-2 is deformed due to the sound pressure of the ultrasonic waves. It is applied to the amplifier 160 via the switching element 122, and the amplifier 160 applies the amplified capacitance to the PCB 20 so that it can be determined whether it is a fake fingerprint.

As described above, the current required for operation is applied from the bias voltage unit 140 to the PZT piezoelectric body 121 via the bias tee 130, and the frequency applied from the signal generator 150 is set to the bias tee It is applied through 130 to maintain high impedance, so that it is possible to determine whether a finger bone is present or not by scanning the amount of blood flow and whether it is a real fingerprint or a fake fingerprint by transmitting and receiving ultrasonic waves. It is accurately determined.

The characteristics of the fingerprint acquired by the electrostatic fingerprint sensor 110 are extracted, compared with fingerprint data pre-stored in the PCB 20, compared with and matched with user's characteristic information to determine whether the fingerprint is the user.

As described above, when recognizing a fingerprint, a fake fingerprint is determined through a complex recognition process, so that a real user can be accurately determined.

While this specification contains many specific implementation details, they should not be construed as limiting on the scope of any invention or claimable, but rather as a description of features that may be unique to a particular embodiment of a particular invention. It should be understood.

On the other hand, the embodiments of the present invention disclosed in the present specification and drawings are only presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is obvious to those skilled in the art that other modified examples based on the technical idea of the present invention can be implemented.

100: fingerprint sensor 110: electrostatic fingerprint sensor
120: ultrasonic sensor 121: PZT piezoelectric
122: switching element 122-1: '+' electrode
122-2: '-' electrode 123: film
130: bias steering 140: bias voltage unit
150: signal generator 160: amplifier
170: epoxy resin 180: bezel

Claims (4)

An electrostatic fingerprint sensor 110 that scans a fingerprint in a semiconductor device method that detects capacitance or electrical conduction so as to obtain image information of a fingerprint;
A fingerprint sensor 100 comprising: an ultrasonic sensor 120 that scans the presence or absence of a finger bone and blood flow in a pulse echo method to determine whether it is a fake fingerprint or a real fingerprint.
According to claim 1,
The ultrasonic sensor 120,
a PZT (Lead Zirconate Titanate) piezoelectric body 121 installed between the switching elements 122;
A plurality of switching elements 122 formed to be spaced apart from each other on the top of the PCB 20 installed inside the fingerprint card 10;
A film 123 installed between the electrode installed on the lower side of the PZT piezoelectric body 121 and the PCB 20;
A forged fingerprint identification device comprising a.
According to claim 1,
The ultrasonic sensor 120,
A counterfeit fingerprint identification device characterized by being installed in an epoxy molding (EMC) 170 formed between the upper panel and the lower panel of the fingerprint card 10.
According to claim 1,
The ultrasonic sensor 120,
A counterfeit fingerprint identification device characterized in that it is installed in the bezel 180 formed between the upper panel and the lower panel of the fingerprint card 10.

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